Climate and Adaptability: A New Look at Evolution in Africa – Part 5

The purpose of this presentation is to show that there could be other forces driving evolution. I have chosen SE Africa because of its important place in the origin of many species including hominoids. This is an alternative view of vertebrate adaptability in SE Africa during the last 20,000 yrs. It considers relative humidity, animal adaptability and migration. This is a six-part analysis of conditions, supported by data, examples and projections of further changes in populations in SE Africa. This should demonstrate that an outside force is driving animal behavior which results in physical and behavioral adaptation and the origin of new species.

Origin of the Species should be revised. This approach was politically and socially motivated. It does not consider alternative views. It postulates that animals and plants genetically adapt to attain an optimum of performance. It implies that there is a narrowing of focus through differentiation that is progressively better. It presumes the philosophical question of a decision tree with an apex. I believe that this view presents a bias of thinking pervasive in the Victorian era.

Although it is implied, there is no proof of progressive improvement in the Darwinian model. Further as we degrade the environment the apex creatures may in fact be the first to go extinct. Depending on your point of view, does increased specialization imply improvement or loss of adaptive capacity? In fact does life and specialization run contrary to the laws of thermodynamics? The second law of thermodynamics predicts that disorganization will prevail. Highly organized life forms will fail but adaptable, simpler life will prevail. The apex creature may be the worst.

An elephant walking through a shallow stream while a safari vehicle passes by on a dirt path.
In this photo the elephant and the safari vehicle are conflicted over passage on a corridor bridge spanning a stream in Tanzania. This is analogous to the resource conflict between humans and the wilderness of the planet.

See the previous posts on these links that led to this site: 1 2 3 4

PROBLEM STATEMENT:

The Theory of Evolution, proposed by Darwin and Russel, is not sufficiently comprehensive to describe the evolving species of mammals in SE  Africa during the period of time starting 20,000 years ago until today.

PURPOSE:

The purpose of this study is to find a challenger to the Darwinian theory. I propose the “Theory of Specialization Extinction”. Understanding this concept should guide plans for research and remedy if that is desirable.

HYPOTHESIS:

There is a relationship of four factors that seem to be the driving forces of evolution which differs from the variables proposed by Darwin: time, animal adaptability, humidity and migration. This is the foundation to the Theory of Specialization Extinction

METHOD:

Assemble a database, query it, and interpret the outcomes. The relationships were plotted in a series of graphs where X axis is time, y axis is animal adaptability, z axis is relative humidity graph. The time line is the past 20,000 years. The location is in SE Africa. Use existing data gleaned from multiple Google searches and derive PYTHON software to plot the relationships.

The following graphics are the results of a 3D plot of the variables in a X,Y,Z cartesian coordinate graph. Accompanying this are 2D images for simplified viewing. On the page left side is the graphic. On the page right side is a summary interpretation of the plots on the graph. Where adaptability is the biological versatility and survival threshold of the regional fauna.

Humidity and animal ADAPTABILITY

3D scatter plot showing the relationship between vertebrate adaptability and climate over time in Southeast Africa, with a timeline extending from 20,000 years before present to the present.

From Knapp

Graph Variables & Dimensions

  • X-Axis (Time): Spans from \(20,000\) years ago (Last Glacial Maximum) to the present day.
  • Y-Axis (Animal Adaptability): Represents the biological versatility and survival threshold of the regional fauna.
  • Z-Axis (Relative Humidity / Moisture): Represents the effective regional moisture, tracking the African Humid Period (approx. \(15,000\) to \(5,000\) years ago) and the subsequent Holocene aridification. [1234]

Fig. 1 A 3D graph plotting time (X), animal adaptability (Y), and relative humidity (Z) for SE Africa shows an inverse correlation.

Deep Purple & Blue (The Past / 20k YBP): These colors represent the earliest part of the timeline, capturing the cold, dry conditions of the Last Glacial Maximum (LGM) [1]. Vertebrate adaptability scores start here.
Vibrant Magenta & Pink (The Climate Pivot / 15k to 5k YBP): This transition color highlights the shift into the African Humid Period [1]. It shows where relative humidity spiked dramatically, expanding habitats and ecosystems [1].
Bright Yellow & Gold (The Modern Era / Present Day): This final color marks the end of the timeline (the present day) [1]. It visualizes the end result of centuries of aridification, where vertebrate adaptability reaches its modern peak due to evolutionary pressures [1].

Key trends shown in the plot include

  • The Humidity Spike (Z-Axis): You will see a clear, high-amplitude “hump” between 15k and 5k YBP. This represents the African Humid Period when mega-lakes expanded across Southern and Eastern Africa.
  • The Adaptability March (Y-Axis): The trend line creeps steadily upward as time advances. Environmental volatility forces a transition away from specialized, delicate ecological niches. This shifts the ecosystem composition toward hyper-adaptable, generalist vertebrate species (e.g., highly mobile bovids, resilient apex predators).

The 20,000-Year Timeline

  • 20,000 to 15,000 Years Ago (Last Glacial Maximum):
    • Z (Humidity): Low. The climate was cool and highly arid caused by glaciation
    • Y (Adaptability): Low to Moderate. Only highly resilient generalist species (versatile feeders and water-independent grazers) persisted in the harsh, patchy grassland habitats. [123]
  • 15,000 to 5,000 Years Ago (African Humid Period):
    • Z (Humidity): High. Monsoon rains expanded into the southern tropics, creating vast, resource-rich savannas and lakes (such as those in the Lake Malawi basin).
    • Y (Adaptability): High. The lush, stable environment allowed for an expansion of both generalist and highly specialized animal species. [12345]
  • 5,000 Years Ago to Present Day (Progressive Acidification): Caused by increased heat. Not by glaciation.
    • Z (Humidity): Decreasing. Regional humidity dropped significantly, causing a return to arid or semi-arid conditions.
    • Y (Adaptability): Bifurcating. Highly specialized taxa (niche foragers) faced extinction, while the surviving fauna demonstrated exceptional, evolutionarily “winnowed” adaptability. [12]. Cats loose. Hyena win.

Fig 2. is a view of the 3D graph showing only the X,Y plane.

A scatter plot showing the relationship between timeline (in years before present) and vertebrate adaptability index, with data points color-coded from purple to yellow indicating adaptability levels from 5 to 9.
Fig. 2 This is a flatten view of the 3D plot to completely ignore the Z-axis (Relative Humidity). This top-down orthographic perspective maps Timeline (X) directly against Vertebrate Adaptability (Y).

Biological Insights from the XY Projection

  • The LGM Bottleneck (20k to 15k YBP): Adaptability scores start low and flat. The harsh, stable aridity of the Last Glacial Maximum kept ecosystems restricted, maintaining low baseline versatility among surviving specialists.
  • The Climate Oscillation (15k to 5k YBP): The curve experiences a downward dip and volatility during the African Humid Period. The sudden abundance of water and lush vegetation temporarily reduced the evolutionary pressure to remain hyper-adaptable, allowing niche, specialized species to briefly flourish.
  • The Modern Filter (5k YBP to Present): As the region dried rapidly, specialized niches vanished. The dramatic upward spike in the index toward the Present shows the evolutionary winnowing effect, where only highly resilient, generalist lineages successfully advanced to the modern era.

Figures 3 and 4 provide similar views of the same information Fig. 3 removes the time variable.

A scatter plot titled 'YZ Plane Projection: Vertebrate Adaptability vs. Relative Humidity' showing the relationship between the Vertebrate Adaptability Index (1-10) on the x-axis and Relative Humidity (%) on the y-axis, with data points color-coded to indicate chronological flow from past (dark purple) to present (yellow).
Fig. 3 Viewing the YZ plane removes the time variable (X-axis) from the visual layout, plotting Vertebrate Adaptability (Y) directly against Relative Humidity (Z).
Because time is hidden, the chronological flow loops backward and forward across the canvas. The data points remain colored from purple (past) to yellow (present) to help you trace the historical direction.

Biological Insights from the YZ Projection

  • The Bottom-Left Start (Deep Purple): Represents the cool, dry Last Glacial Maximum (low humidity, low-to-moderate adaptability baseline).
  • The Upward Loop (Pink/Magenta): Tracks the onset of the African Humid Period. Humidity shoots up toward \(80\%\), creating highly stable, lush conditions. Notice how the line hooks slightly downward or stays stable in adaptability hereโ€”this shows environmental abundance temporarily lifting the pressure to remain universally adaptable, giving specialized vertebrates room to diversify.
  • The Modern Filter (Yellow/Gold): Tracks the crash in relative humidity back toward \(40\%\). As moisture vanishes, the trajectory lunges violently to the right, concentrating heavily at the highest adaptability index values. This isolates the modern faunal profile: a community dominated by highly versatile generalists surviving in an arid landscape.
3D scatter plot showing the relationship between the Vertebrate Adaptability Index (1-10) and Relative Humidity (%). The plot features a color gradient representing a hidden timeline from past (dark) to present (light).

Visual and Environmental Mechanics

  • The X-Axis Compression: Notice how the bounding box collapses into a 2D wall. The timeline depth is now indicated purely by the shift from dark purple dots to yellow dots.
  • The Loop Shape: This visualization isolates the environmental cycle. The curve shows that while humidity fluctuated drastically over thousands of years (moving up and down the vertical scale), vertebrate adaptability was forced into a massive net migration rightward across the horizontal axis due to long-term aridification.

Fig. 4 is an orthographic view showing compression of the data .

Humidity and migration

Here is evidence of relative humidity directly influencing mass migration intensity

Line graph illustrating the relationship between vertebrate mass migration intensity and relative humidity in Southeast Africa over time. The blue line represents relative humidity, while the red line shows mass migration event intensity, with data spanning from 20,000 years before present to the present.
Fig . 5 The primary drivers of vertebrate mass migrations are climate transitions. By plotting Relative Humidity and Mass Migration Intensity on a shared time axis, we can clearly observe how severe climate changes trigger ecological shifts.

Eco-Historical Analysis

  • The Green Corridor Expansion (~14,000 YBP): As the African Humid Period began, a minor migration spike occurred. Large herbivores and their predators migrated northward and inward, tracking the rapid expansion of savannas and wetlands.
  • The Humid Equilibrium (~13,000 to 6,000 YBP): During this period, migration rates remained low. Highly reliable water sources in Southeast African river basins (like the Zambezi and Limpopo systems) allowed animal populations to establish stable, local ranges.
  • The Great Aridification Push (~5,000 YBP): This period shows a sharp spike in mass migration. As water holes dried up, massive herds of large mammals were forced to migrate long distances to find permanent water sources. This intense environmental pressure acted as an evolutionary filter, favoring highly adaptable generalist species.
3D scatter plot depicting the Adaptability, Humidity, and Migration patterns of vertebrates in Southeast Africa over time, with data points color-coded from purple (past) to yellow (present).
Fig. 6 To visualize four dimensions simultaneouslyโ€”Timeline (X), Vertebrate Adaptability (Y), Relative Humidity (Z), and Mass Migration Intensityโ€”we can plot a 3D trajectory path where the thickness of the line dynamically changes to represent migration surges.

Interpreting the 4D Synergies

  • The Humid Period Buffer (15k to 5k YBP): As the trajectory climbs along the vertical Z-axis (Humidity), the line stays thin and adaptability dips. High moisture reduced the pressure to adapt, allowing specialists to settle locally without needing to migrate.
  • The Late-Holocene Collapse (~5k YBP): As humidity collapses down the vertical axis, the line thickens significantly. This thick segment represents massive migration pulses driven by resource scarcity.
  • The Evolutionary End State (Present Day): The path ends at the far right of the chart (highest adaptability index) in bright yellow. This illustrates how climate-driven migrations permanently altered the ecosystem, leaving behind a resilient, highly adaptable faunal population.
  • Figure 7 may be easier to comprehend.
Graph depicting the macro-ecological dashboard of Southeast Africa over the past 20,000 years, featuring three charts: relative humidity percentage, migration intensity, and vertebrate adaptability index.
Fig. 7 This is a 2D multi-panel dashboard plot designed to view all four environmental and biological variables side-by-side. Below the plot, you will find the specific fossil records and archaeological evidence from SE Africa that validate the modeled migration spikes.

Archaeological and Fossil Evidence in Southeast Africa

The migration spikes and adaptability transitions modeled in the dashboard mirror real-world paleontology and archaeology findings across Southeast Africa (encompassing Mozambique, Malawi, Zimbabwe, and eastern South Africa).

Archaeological and Fossil Evidence of animal activity reflecting adaptability in SE Africa

The term pulse implies large movement of the animals along low barrier corridors in response to climate shift. The animals follow the water.

1. Pulse 1 Evidence (~14,000 YBP – The Open Savannah Expansion)

  • Fossil Records (Bovid Turnover): Fossil assemblages from sites like Wonderwerk Cave and Shongweni show a dramatic turnover in mammalian fauna at the end of the Last Glacial Maximum (LGM). As the climate shifted toward the African Humid Period, dry-grassland specialists (like the extinct giant equine Equus capensis) vanished or migrated out, replaced rapidly by water-dependent, browsing, and mixed-feeding bovids.
  • Archaeological Evidence (Tool-kit Transitions): Human populations tracked these shifting game migrations. Archaeological layers from the transition to the Robberg and Oakhurst technocomplexes reveal a sudden change in hunting equipment. Large stone segments used for hunting open-plains migratory herds gave way to smaller, diverse tools optimized for trapping and hunting non-migratory bush-dwelling animals as woodlands expanded.

2. The Humid Period Stabilization (~15,000 to 5,000 YBP)

  • Lake Malawi Sediment Cores: Core samples from Lake Malawi show high lake levels and dense surrounding forest cover during this window. Fossil pollen and micro-faunal remains confirm stable, localized populations. Animals did not need to undergo high-intensity, desperate mass migrations because resource baselines were rich and stationary.

3. Pulse 2 Evidence (~5,000 YBP – The Great Aridification Filter)

  • The Refugia Bottleneck: As SE Africa rapidly dried out around 5,000 years ago, animals migrated en masse toward permanent water networksโ€”specifically the Limpopo and Zambezi River basins. Fossil bone beds in these valley zones show dense, hyper-concentrated mixtures of diverse animal remains from this era, confirming they served as environmental “refugia” where species huddled to survive.
  • Extinction and the Generalist Winnowing: Niche-dependent, specialized megafauna suffered severe localized extinctions. The fossil layers moving into the Late Holocene show a stark homogenization: specialized grazing species are missing, leaving behind the exact highly adaptable, generalist survivors we see today (e.g., impalas, kudus, spotted hyenas).
  • Human Forager Disruption: Archaeological sites across Zimbabwe and Mozambique document a matching disruption in human behavior. The Wilton culture hunter-gatherers abandoned many open inland sites completely around 5,000โ€“4,000 YBP, tracking the migrating game lines to settle permanently along coastal zones or river valleys where permanent water persisted.

Future Bidirectional Wildlife Corridors (2026โ€“2100)

In the coming decades, animal migrations in East Africa will move along a specific north-south coastal ribbon of land. This corridor is bordered by the Indian Ocean to the east and the “Great Mountain Wall” to the westโ€”a rugged barrier formed by the eastern branch of the East African Rift, including the Southern Highlands, the Eastern Arc Mountains, and Mount Kilimanjaro.

As climate shifts alter regional moisture, wildlife will rely on this coastal strip for survival. They will follow this route:

               [ NORTHERN TERMINUS: Horn of Africa / Somalia ]
                                  โ–ฒ      โ”‚
                                  โ”‚      โ”‚
     THE GREAT                    โ”‚      โ–ผ
   MOUNTAIN WALL         [ EQUATORIAL ECOTONE: Tana & Galana Basins ]
 (Rift Escarpments,               โ–ฒ      โ”‚
  Eastern Arc Mts,                โ”‚      โ–ผ
 Kilimanjaro, Kenya              [ INTERMEDIATE SAVANNA: Tsavo-Mkomazi Corridor ]
   Dome Uplands)                  โ–ฒ      โ”‚
                                  โ”‚      โ–ผ
                         [ MARITIME REFUGE: Rufiji & Ruvuma River Systems ]
                                  โ–ฒ      โ”‚
                                  โ”‚      โ–ผ
               [ SOUTHERN TERMINUS: Greater Limpopo / Gorongosa ]
Map illustrating the Eastern Afromontane Biological Corridor, featuring migration routes and ecological links between Kenya, Tanzania, and Mozambique. Highlighted regions include the Tana-Galana Equatorial Ecotone, Mkomazi-Tsavo Arid-Savanna Link, and Ruvuma-Rufiji Maritime Fluvial Conduit, showcasing various wildlife such as elephants, colobus monkeys, and migratory birds.
This graphic shows the three corridors. The Ruvuma is not physically interconnected to the others. The animals circle about but there is no place for escape.

These three routs will provide key bidirectional corridors which will be followed as the climate shifts. These will allow limited local migration. There is no longer an escape from SE Africa as aridification intensifies and desertification becomes irreversible.

1. The Ruvuma-Rufiji Maritime Fluvial Conduit

  • Geography: Connects northern Mozambique (Gorongosa and Niassa) across the Ruvuma River into southern Tanzania (Selous/Nyerere Ecosystem).
  • Northward Pulse (Wet-Season Dispersal): Driven by expanding summer monsoons, water-dependent megafauna (elephants, buffaloes) will push north along the coastal plains.
  • Southward Pulse (Dry-Season Retreat): As interior grasslands dry up, wildlife will move south, tracking reliable water in the permanent Ruvuma and Rufiji river networks.

2. The Mkomazi-Tsavo Arid-Savanna Link

  • Geography: Straddles the Tanzania-Kenya border, running squeezed between the Usambara Mountains and the ocean.
  • Northward Pulse (Xeric Colonization): Highly adaptable, drought-tolerant species (oryx, gerenuk, lesser kudu) will push north into Tsavo as it becomes more arid.
  • Southward Pulse (Rift-Fringe Buffer): Zebra and wildebeest populations will move south toward the wetter mountain foothills when coastal plains dry out.

3. The Tana-Galana Equatorial Ecotone

  • Geography: Runs through eastern Kenya up to the Somali border, acting as a critical buffer zone just east of the Kenyan Highlands.
  • Northward Pulse (Opportunistic Browsing): Giraffes and resilient browsers will move north during brief, intense rainfall spikes.
  • Southward Pulse (Hyper-Arid Push): Extreme droughts in the Horn of Africa will force northern species to migrate south toward the permanent Tana River basin for survival.

This is a Species-Specific Survival Outlook indicating COMPARATIVE survival (2026โ€“2100)

Based on the presentation of this and the last four postings this is my projection for the next 75 years. Table 1 is the migration behavior timeline correlated to climate benchmarks

Micro drivers of adaptability

Climate EraProjected TimeframePrincipal Climate DriverExpected Migration Dynamics
Short-Term Baseline2026 โ€“ 2040Increased frequency of Indian Ocean Dipole (IOD) anomalies.Highly erratic, localized pulses. Erratic weather triggers unseasonal migrations between protected parks. Wildlife increasingly relies on community-managed conservancies outside park boundaries.
Mid-Century Shift2041 โ€“ 2070Aridification of the interior; expansion of coastal savannas.Consolidated north-south corridors. Large-scale migrations lock into a north-south pattern along the coast. Favorable eco-zones contract, squeezing animals between human infrastructure and the mountains.
Long-Term Equilibrium2071 โ€“ 2100+Permanent hyper-aridity in the Horn; the coastal savanna shifts inland.Systemic bidirectional loops. Long-distance migrations become highly synchronized. Resilient, generalist species dominate these routes, while specialized species are limited to small mountain refuges.
Table 1. Migration timeline and dynamics

Transecting Infrastructure CAUSING Bottlenecks & Blockades

To assess how these vital coastal corridors will function through the end of the century, we must look at how future infrastructure blockades collide with the survival traits of specific indicator large mammals. Squeezed between the Indian Ocean and the Great Mountain Wall, wildlife will face unprecedented structural bottlenecks.

Some animals will be restricted because of these three major east-west transport corridors which run completely perpendicular to the north-south migration routes. They will act as physical barriers to those species which cannot physically overcome the obstacles of topography, traffic, fences and human presence. They are listed here [1, 2]:

  [ NORTHERN TERMINUS: Horn of Africa / Somalia ]
       โ”‚
       โ–ผ
  [====== LAPSSET Corridor (Lamu-Port-South Sudan-Ethiopia Highway/Rail) ======]
       โ”‚
       โ–ผ
  [====== Northern Corridor (Mombasa-Nairobi SGR Railway / A109 Highway) ======]
       โ”‚
       โ–ผ
  [====== Central Corridor (Dar es Salaam-Morogoro-Dodoma Standard Gauge Rail) =]
       โ”‚
       โ–ผ
  [ SOUTHERN TERMINUS: Greater Limpopo / Gorongosa Ecosystem ]

These are some of the problematic causal locations and issues:

  1. The Central Corridor (Tanzania): The newly operational Dar es Salaamโ€“Morogoroโ€“Dodoma Standard Gauge Railway (SGR) [3] cuts directly across the northern exit of the Selous/Nyerere ecosystem. Its fencing and elevated tracks force elephants and buffaloes into narrow, artificial underpasses.
  2. The Northern Corridor (Kenya): The Mombasaโ€“Nairobi SGR [4] and parallel A109 highway sever the Tsavo East and Tsavo West ecosystems. While some elevated viaducts exist, increased traffic makes crossing dangerous for large herds.
  3. The LAPSSET Corridor (Northern Kenya): This mega-project cuts straight across the Tana River basin up to Lamu [5]. It creates a final, major barrier for animals attempting to migrate between Kenya and Somalia.

Depending on their skill set, groups of different species will handle these infrastructure barriers and climate shifts in very different ways. Here are groups 1. Generalists and 2 Specialists.

                  โ”Œโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”
                  โ”‚      SPECIES SURVIVAL PROFILES         โ”‚
                  โ””โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”˜
                                      โ”‚
         โ”Œโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”ดโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”
         โ–ผ                                                         โ–ผ
โ”Œโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”                       โ”Œโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”
โ”‚    1.THE ADAPTABLE GENERALIST   โ”‚                       โ”‚    2. THE STRANDED SPECIALIST   โ”‚
โ”‚  (High Mobility / Resilient)    โ”‚                       โ”‚   (Fencing Vulnerable / Niche)  โ”‚
โ”œโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”ค                       โ”œโ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”ค
โ”‚ โ€ข African Bush Elephant         โ”‚                       โ”‚ โ€ข Blue Wildebeest               โ”‚
โ”‚ โ€ข Spotted Hyena                 โ”‚                       โ”‚ โ€ข Reticulated Giraffe           โ”‚
โ”‚ โ€ข Plains Zebra                  โ”‚                       โ”‚ โ€ข Coastal Topi / Hirola         โ”‚
โ””โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”˜                       โ””โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”€โ”˜

Flow diagram. Group 1: The diverse, adaptable skill set group. Group 2. The generalists (High Survival Probability)

Group 1:

  • African Bush Elephant (Loxodonta africana):
    • Traits: High cognitive mapping, long-distance memory, and sheer physical power.
    • Outlook: Elephants are highly adaptable. They learn to actively navigate infrastructure by locating underpasses or breaking through weak fencing when necessary. They will easily use the Ruvuma-Rufiji conduit to track water resources.
  • Spotted Hyena (Crocuta crocuta):
    • Traits: Extremely diverse diet, nocturnal flexibility, and comfortable around human landscapes.
    • Outlook: Hyenas can move easily through fragmented zones. They will use drainage culverts and road shoulders to cross highways, thriving along the corridors by scavenging on roadkill and livestock.

Group 2: The Stranded Specialists (High Extinction Risk)

  • Blue Wildebeest (Connochaetes taurinus):
    • Traits: Rely on open, unfenced pathways to track seasonal rains.
    • Outlook: Wildebeest are highly vulnerable to fencing. Unlike elephants, they will not challenge a fence line and lack the agility to leap over barriers. The Tsavo-Mkomazi link will likely see localized wildebeest collapses as linear infrastructure seals off their routes.
  • Reticulated Giraffe (Giraffa camelopardalis reticulata):
    • Traits: Limited agility; anatomically incapable of using standard railway underpasses or low viaducts.
    • Outlook: Giraffes are easily trapped by fences and overpasses. The LAPSSET and Northern corridors risk completely splitting northern giraffe populations from southern ones, leading to isolated, vulnerable genetic pockets.

The Four Macro-Drivers of Adaptability that parallel humidity for causality

While relative humidity directly dictates water availability and respiratory comfort, it operates alongside three other major catalysts for adaptation. I believe that there are several macro-environmental drivers that influence animal adaptability similarly to or even greater than relative humidity. In the table below you see how four core forces compare. Relative humidity is at the bottom. These factors drive evolutionary changes and animal movements east of the great mountain wall. This study shows that at least one outside force could also be driving evolution. There may be other forces but as a working hypothesis these four deserve further research. I picked relative humidity for this discussion because it was the most evident while we were traveling.

Evolutionary DriverInfluence LevelPrimary Biological MechanismReal-World Impact in East/Southeast Africa
1. Net Primary Productivity (NPP)GreaterFood web energy, caloric baseline, and vegetation structure.Dictates the exact carrying capacity of savannahs. When NPP drops, large grazers face immediate starvation.
2. Ambient Temperature DynamicsEqualMetabolic rates, thermal stress boundaries, and water-loss velocity.Forces species into higher altitudes or dense shade to prevent dangerous overheating.
3. Landscape Roughness / TopographyEqualPhysical barriers, escape terrain, and microclimate patches.The Great Mountain Wall protects localized species by trapping moisture, even during regional droughts.
4. Relative Humidity (Baseline)ReferenceHydration balance, disease transmission, and evaporation rates.Sets the broad boundaries for wet-forest vs. hyper-arid ecosystems.
Table 2.

The following are details of the evolutionary drivers listed in Table 2

1. Net Primary Productivity (NPP) โ€” This shows why food is more influential than simple moisture

While humidity creates the climate background, Net Primary Productivity (the total amount of edible plant biomass generated by an ecosystem) is the ultimate filter for survival.

  • The Energy Filter: An animal can survive low humidity, if it has access to moisture-rich roots, succulent leaves, or prey. NPP represents the actual fuel available to the food web.
  • Adaptability Impact: When NPP drops, it triggers aggressive evolutionary pressure. This pressure favors hyper-adaptable mixed-feeders (like elephants and impalas) that can instantly switch from eating grass to chewing bark and twigs, thus outperforming picky, specialized leaf-eaters.

2. Ambient Temperature Dynamics & Thermal Scaling

Temperature variations often overpower humidity by pushing animals past their absolute physical limits.

  • Metabolic and Water Costs: As temperatures rise, the amount of water an animal loses through panting or sweating increases exponentially.
  • Adaptability Impact: High temperatures favor animals with clever cooling traits. This includes physical adaptations like the massive, heat-shedding ears of the elephant, behavioral shifts like becoming completely nocturnal, or physiological tricks like the gemsbokโ€™s ability to let its core body temperature safely spike during the day to save water.

3. Topographic Heterogeneity (Landscape Roughness)

Recall from our first episode of this saga. The physical shape of the landโ€”specifically the Great Mountain Wallโ€”exerts a massive, nearly permanent influence on animal adaptability by creating reliable environmental safety nets.

  • Microclimate Buffers: Flat plains offer no escape during a drought. In contrast, rugged mountain terrains create a patchwork of different microclimates, offering cooler temperatures and trapped moisture just a short climb away.
  • Adaptability Impact: Complex landscapes allow less-adaptable, specialized species to survive in isolated mountain pockets (refugia) for thousands of years, completely shielded from the harsh changes happening on the open plains below.

CONCLUSION:

Combining the micro drivers, macro drivers and the transecting human infrastructures, animals will not escape. They will die from lack of water, starvation and over heating. Exquisitely wondrous, specialized species will vanish with no successor species to follow. Should we continue as we have or rewild to a state of 200 years ago or work for a better future?

We have completed the cat comparisons and with this effort shown that the theory of evolution should be subject to review and perhaps modification. The Theory of Specialization Extinction is incomplete without evidence and proof of concept. In order to provide evidence of this concept four things are needed. A well formulated scientific study. A rigorous review of the literature. A more comprehensive data base that includes not only the endangered species but also the support environment in which they live and the resources upon which they depend. A comprehensive plan for future management.

In a future post we will discuss what may be done to track cheetah, lions and all of the other animal species simultaneously. This would tell us where in lie the problems that may be remedied.

I hope that you enjoyed the pictures along the way. Here are pictures if the animals most likely to survive:

Two hyenas standing on a grassy field, with one facing forward and the other turning slightly to the side.
Spotted Hyena
A zebra standing beside a tree in a grassy field, showcasing its distinct black and white stripes.
Planes Zebra
A group of elephants, including a baby elephant, drinking water at a waterhole, with some water droplets visible.
African Bush Elephant

ADDITIONAL REFERENCES:

https://www.researchgate.net/publication/230607856_Evidence_for_progressive_Holocene_aridification_in_southern Africa_recorded_in_Namibian_hyrax_middens_Implications_for_African_Monsoon_dynamics_and_the_”African_Humid_Period”

Click to access PRINTED-Vet-No14-Aug2023.pdf

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#humidity #last glacial period #adaptability #time #Africa #survivor #bottleneck #aridification #extinction #temperature #productivity #climate #migration #corridor #hyenas #elephants #zebras #specialization

Cheetahs and Lions Trapped by Time and Place – The Theory of Specialization Extinction – Part 3

INTRODUCTION

This presentation is the third in a series of blogs that uses the example of Cheetahs and Lions to show the survivability effects of evolving specialization. The first in the series lays the foundation of geography, climate and time. The second compared two African cats; Lions and Cheetahs. This presentation introduces the concept of traps. The “traps” are made of time, location, resources and specializations. They put these cats at risk for survival. Survival of the species depends on behavioral modification, physiologic adaptation and selection by desirable mating. We may have exposed ourselves to the same traps. This is not about mechanical traps. These are more insidious.

In The opening video clip – The “traps in this presentation are UNINTENTIONALLY generated by the animal’s remarkable behavior and adaptations. They are more SIGNIFICANT than physical traps

Traps are the delimiters that block biologic adaptation to a changing environment. Inability to overcome traps leads to extinction. It is not about survival of the fittest. It is about survival of the most adaptable. This is the reason to study the survival of these two cats. Understanding the pitfalls will reflect on the survival of everything, specifically us.

In order to discuss unintentional consequences of behavior leading to traps, I suggest that we review of the work of the naturalists of the 18th century. Several theories had been proposed. The most notable is the Theory of Evolution. Darwin and Wallace proposed the foundational ideas. Survival of the fittest forces the origin of species. Additionally, isolation promotes differentiation. In the view of these observers of nature, there is a progressive change in the survival of the majority. I propose an alternative view of the Darwinian theory. Let’s call this the Theory of Specialized Extinction.

THEORY OF EVOLUTION

I respect the pioneering publication of the books of Charles Darwin. These include The Beagle diary (1839), Origin of the Species (1859) and The Descent of Man, and Selection in Relation to Sex (1871). I first read these 66 years ago when I was in high school. Here are the tenants of his theory. My comments are in italics.

Overproduction: Organisms produce more offspring than their local environment can support, which leads to competition for limited resources. Alternatively, it may lead to cooperation, revolution or migration.
Variation: Individuals within a single species naturally display a wide range of variation in their physical traits, behaviors, and genetic makeup. This suggests that there are mutations in the population.
Inheritance: Many of these unique variations are heritableโ€”meaning they can be passed down from parents to their offspring. This does not take into consideration dominant and recessive genes.
Differential Survival & Reproduction: Individuals possessing traits best adapted to their specific environment (“survival of the fittest”) are more likely to survive threats and successfully reproduce. If individuals are highly specialized they may not be able to adapt to the changing environment.
Descent with Modification: Over vast expanses of time, these advantageous traits become more common in the population. Gradually, this accumulation of changes can lead to the emergence of entirely new species. The rate of accumulation of traits depends on the complexity of the organism. The accumulation of traits does not necessarily lead to new species but may lead to species vulnerabilities.

Most of Darwin’s work suggests a time line with a steady progression of change, most of which was deemed to be an improvement. In prospect most of his writing appears to be intrinsically biased. Yes, there is change, however, it is coincidental with “implicit bias”. It does not confirm causality. Additionally, an apex implies that there is a narrowing of differentiation that is progressively better. It presumes the philosophical question of a decision tree which has an apex. It does not imply value to alternative views.

Although it is implied, there is no proof of progressive improvement in the Darwinian model. In fact, as we rapidly degrade the environment the apex creatures may be the first to go extinct. Depending on your point of view, does increased specialization imply improvement or loss of adaptive capacity? In fact does life and specialization run contrary to the laws of thermodynamics. The second law predicts disorganization.

A horizontal continuum for example could be applied to the time line of species differentiation. Here is a visual representation of a relationship between and among animal adaptability and humidity during the recent 20,000-year history of the area. I picked humidity because, as you could see in our previous presentations, desertification was the most prominent aspect of the environments we explored.

3D scatter plot showing vertebrate adaptability index versus climate matrix over a timeline from 20,000 years before present to the present. The plot features colored data points indicating adaptability levels across different time periods.

X-Axis (Time): Spans from \(20,000\) years ago (Last Glacial Maximum) to the present day.
Y-Axis (Animal Adaptability): Represents the biological versatility and survival threshold of the regional fauna.
Z-Axis (Relative Humidity / Moisture): Represents the effective regional moisture, tracking the African Humid Period (approx. \(15,000\) to \(5,000\) years ago) and the subsequent Holocene aridification

Please see the extensive discussion of this in the following posting titled Exploring Animal Adaptability in Southeast Africa.

The 20,000-Year Timeline

  • 20,000 to 15,000 Years Ago (Last Glacial Maximum):
    • Z (Humidity): Low. The climate was cool and highly arid.
    • Y (Adaptability): Low to Moderate. Only highly resilient generalist species (versatile feeders and water-independent grazers) persisted in the harsh, patchy grassland habitats. [123]
  • 15,000 to 5,000 Years Ago (African Humid Period):
    • Z (Humidity): High. Monsoon rains expanded into the southern tropics, creating vast, resource-rich savannas and lakes (such as those in the Lake Malawi basin).
    • Y (Adaptability): High. The lush, stable environment allowed for an expansion of both generalist and highly specialized animal species. [12345]
  • 5,000 Years Ago to Present Day (Progressive Aridification):
    • Z (Humidity): Decreasing. Regional humidity dropped significantly, causing a return to arid or semi-arid conditions.
    • Y (Adaptability): Bifurcating. Highly specialized taxa (niche foragers) faced extinction, while the surviving fauna demonstrated exceptional, evolutionarily “winnowed” adaptability. [12]

Theory of SPECIALIZED extinction

Specialized Extinction is progressive reduction of life forms. It is the unspecified opposite of Darwin’s theory. Please recall that Darwin’s work of the mid 1800s predated the current concepts of ecology, genetics, statistics, modern scientific method, advances in understanding of natural history, microbiology, plate tectonics, climate change, extraterrestrial incidents, human behavior, etc.

We are experiencing the reverse of the origin of the species. This is the loss of the species variations. Species vary in response to environmental pressure. Without necessity there is no invention. With environmental change only the adaptable will survive.

MASS EXTINCTIONS

During the ice age animals located in water compromised areas or in cold climates faced environmental pressure. Many were not capable of adapting with sufficient rapidity to the changes. The advancing cold wall of ice combined with the massive dust storms which ripped across the deserts of the planes starved, froze or buried millions as they struggled to compete for diminishing food and water. These climatic events resulted in loss of thousands of species, of fauna and flora of the northern continental masses.

This process of extermination was exaggerated by bottleneck effect and genetic drift.

Illustration of genetic drift in frog populations, showing a funnel shape with green and red frogs at the top, labeled with 'death' and 'invasion,' leading to a diverse green population at the bottom.
Fig 1
Illustration explaining the bottleneck effect in population genetics, showing three stages: original population in a bottle, a bottleneck event reducing the population, and the surviving population in a cup, with a graph depicting population size over time.
Fig 2

Fig 1 and Fig 2 are two variations on population behavior that limit the genetic pool of diversified genomes.

In Fig. 1 This can happen when the genetic pool is insufficient to maintain variance. The largest constituent group are light and dark green. If the orange portion dies and the purple portion does not invade, then the survivors can only reproduce mixed green progeny.

In Fig. 2 In the biologic bottleneck only a few members of the population escape. In this case the green did not pass the bottleneck. Those that did act are founders of a new community with a more exclusive population. Since only one yellow member passed the bottleneck it represents an extinction effect unless it can hybridize with the blue members. If not it will die thus ending that part of the population. Hybridization may result in a recovery of the population that will not be exclusively blue. Alternatively, with recessive traits the population will recover with a Mendelian result.

The well known traps are outlined below. I suggest that the study of these traps may challenge the initial concepts theorized by Darwin.

TRAPS DEFINED

By specialization animal abilities to avoid these traps are disadvantaged.

Specialization Trap is where the animals of a species undergoes physical evolution to match their environment. This results in highly efficient but physically fragile animals who cannot cope with the changes in their environment that occur faster than they can adapt. This includes many species and may be a natural process. Loss of one non-adapting species makes room for another. This is consistent with Darwinian “Natural Selection”.

Genetic Bottleneck Trap results in reduced adaptability. When the population reaches a point of limited genetic variation there is insufficient capacity to adapt to environmental changes, such as climate change or new diseases.

Genetic Drift Trap results in lack of genetic diversity.

Declining Prey Base Trap is a broad based result of all the regional population of mutually entangled species with an extremely low general DNA variance.

Habitat Fragmentation Trap prevents the massive, free-roaming across territories. Without corridors, species cannot migrate to compatible environments. Conversely, species variants can immigrate into territories thereby promoting hybridization.

Daylight Hunting Trap Prevents animals from night hunting while hot, dry daytime conditions become intolerable

Human-Wildlife Conflict. Genocidal hunting, trapping and habitat destruction by farming and mining at industrial scale combine to make the ultimate trap.

CHEETAH

Cheetah are likely a distinct, naturally evolved species (Acinonyx jubatus) belonging to the small-cat lineage (Felinae). Their closest living relatives are the puma (mountain lion) and the jaguarundi. They cannot be naturally hybridized with other members of the Felinea because they are just too different. They split from the rest of the cat family tree millions of years ago and are the sole members of their own unique genus, Acinonyx.

  • They are not related to the Pantherinae (Lions, which started in Africa)
  • Cheetah existed secondary to late Pleistocene bottleneck extinctions 100K to 12K years ago.

Cheetahs are believed to have survived the two ice age catastrophic population bottlenecks that nearly drove the species to extinction. [12] The root causes of cheetah’s problems were the two historic climatic bottlenecks plus their great speed. They were able to quickly run ahead of their competitors and ranged widely looking for prey. They out ran their competitors and extended beyond their base population. As small groups continuously separated from their peers they formed new island clusters. These founder effect groups were cut off from hybridization and experienced genetic drift. In summary:

  • They are not related to the Pantherinae (Lions, which started in Africa)
  • Cheetah existed secondary to late Pleistocene bottleneck extinctions 100K to 12K years ago.
  • Cheetah developed in the Asia/Americas and are related to domestic cats. 
  • Extremely inbred with depressed dominant traits.
  • They are all near identical clones: Completely depleted of variation in their genomes
  • They are experiencing founder effect. Africa is their CULMINATING POINT

LION

As a member of the big cat family these animals were born and bred in Africa. Modern lions diverged and began to leave its earliest fossilized footprints in East Africa around 2 to 3 million years ago. Through a combination of geographic refugia, extreme dietary flexibility, and evolutionary teamwork the lions thrived in the dry, ice free planes of Africa.

Cheetah and Lion – SUBJECTED TO time, relative humidity and LEVEL of adaptability

Over the last 20,000 years in Southeast Africa, climate shifts drastically altered humidity and ecosystems. The region swung between severe arid phases (like the Last Glacial Maximum) and the highly humid African Humid Period. In that period animal adaptability peaked. Generalist species thrived by adjusting to habitats, while specialists faced selective extinction. [1234] Some mammalian species failed to track their preferred climates over the last several thousand years. The failure to either migrate or adapt quickly may be their obstacle to survive. There is a significant time lag between climate change and speciesโ€™ responses. These two cats were able to survive. The African Saber-toothed Cats, Scimitar Cats, Eastern Koppard and the Giant Cheetahs did not make it through the last 50,000 to 10,000 years.

Below is a four-column table of paleoclimatic and evolutionary timeline outlining the historical shifts:[12]

Time (Years Ago) [1234567891011]Relative Humidity (Z-Axis)Animal Adaptability & Response (Y-Axis)Environmental Context
20,000 – 15,000Very Low(Dry / Arid)High (Specialist Die-off / Generalist Shift)Last Glacial Maximum. Equatorial lakes dried, forcing animals to adapt to sparse resources.
15,000 – 11,500Increasing(Transition)Moderate to High (Adaptive radiation)Deglaciation. Climate instability introduced genetic variance and rapid adaptation (“variability selection”).
11,500 – 5,000Very High(Wet / Humid)High (Biodiversity Boom)African Humid Period. Savannas expanded, and water-reliant generalist species thrived and spread.
5,000 – 2,000Decreasing(Drying Trend)High (Behavioral Adaptability)Monsoons weakened, leading to progressive desertification and forcing animals/humans into complex, mixed-habitat strategies.
2,000 – PresentModerate / VariableHighModern climate regimes. Continuous micro-adaptations are documented, though global warming increasingly tests limits.
Table 2. Variables and Environmental Context

This is the scenario of failure to survive, the theory should be called “THE THEORY of SPECIALIZED EXTINCTION” The tenants of this are

  • Reproduction with wide ranging genetic adaptability
  • Environmental change
  • Differential reproduction based on past environments
  • Extinction by environmental change

THE EFFECTS OF THIS ON PEOPLE TODAY

A very small hominoid population (likely Homo heidelbergensis or Homo erectus) expanded before 900,000-800,000 years ago. It underwent a massive glacial bottleneck which lasted for 100,000 years. The population was reduced to ~1200 individuals. This lengthy event killed off so much of the population that it irreversibly reduced the genetic diversity of the species. The effects of that have persisted until today. Even though chimpanzees and gorillas might look similar to us, they have many more times the genetic diversity within their species than humans.

CONCLUSION:

We can conclude that developing survival strength through unique specialization may be a death trap. To do this we followed cheetahs and lions as they adapt and survived through the last 20,000 years. There was an entire eco system which followed the same path. We should pay more attention to the generalists. Survival by adaptation to environmental change is more advantageous than specialization. Ability to change our environment may be our only survival option.

In our next posting (Exploring Animal Adaptability in Southeast Africa) we will try to project the future of the fauna for the next 50 years. See you there !

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REFERENCES

uhttps://www.science.org/content/article/carnivorous-ballet-helps-cheetahs-coexist-lions

uhttps://www.wildlifenomads.com/blog/cheetah-facts/

uhttp://www.macroevolution.net/natural-selection.html

Adaptive introgression

uhttps://evolution.berkeley.edu/evo-news/will-evolution-doom-the-cheetah/

uhttps://evolution.berkeley.edu/triggering-adaptive-radiation/

uhttps://evolution.berkeley.edu/evolution-101/macroevolution/

# Cheetah #lions #traps #genetic drift #bottleneck #adaptability #evolution #environment #founder effect #survival

Glacial Formation and Plate Tectonics Influence Species Survival in Africa – Part 1

Part ITectonics, Glaciers and Time

A few zebras and wildebeests grazing in the desert of the Ngorongoro Crater of Tanzania, with two safari vehicles in the background kicking up dust.
Fig. 3 Ngorongoro Crater in Tanzania, 2025 desertification

Introduction

The terrestrial forces of tectonic plate movement, ice ages and volcanic activity, together have changed the earth like no other forces except collision with extraterrestrial bodies. Southeast Africa has strategically benefited from these earth changing forces. This can be seen in the generation of a widely varied collection of mega and micro fauna and flora like no other place.

A panoramic view of a vast green landscape with patches of water, hills in the background, and a clear blue sky.
Fig. 10 The Ngorongoro 5 years ago.

The introduction picture shows a 7 zebras and 5 wildebeest in the Ngorongoro Crater. We went there using safari vehicles in 8/2025. The only road was made of irregular stones, ruts and dirt. Driving was difficult. Visibility was obscured for hours by dust as we drove across the crater. It is the caldera of the worlds largest above water volcano that was active 2.5 million years ago. It was famous for its wildlife. The image shows the greatest concentration of animals which we encountered along the way. To say that it was disappointing is an understatement. Fig. 10 comes from a posting on the internet.

Changing forces

Today we can see that the forces are changing. Tectonic plate is the slowest acting force acting in the level of hundreds of millions of years. And yet its rate and direction of movement can change dramatically in regions. This may be caused because glaciers and ice shelves are reduced. Glacialization operates at more rapid rate than plate movement with an effective speed measured in thousands of years. As the ice melts the weight of the water is more evenly distributed to the oceans thus altering the plate movement location and location of volcanic activity. Notably, the rate of vulcanism is unchanged. Volcanic ash, carbon dioxide and sulphur and gases are insignificant when compared to human activity. Anthropogenic CO2 emission for 2010 is estimated to be about 80 to 270 times larger than the respective maximum and minimum annual global volcanic CO2 emission. The results of action and reaction of human intervention parallel a cause and effect interference with historic geologic cyclical behavior. This may be the root cause of two possible effects of biological changes which are currently occurring. Survival of existing species is in decline. Generation of new species has slowed. This series of postings uses a contrast of two cat species, lions and cheetahs in Southeast Africa. Study of these species is intended to form a foundation for understanding how the change in the forces drive the current ecological conditions.

These four blogs are the result of thoughts and interpretations based on our latest safari to Africa that included Kenya and Tanzania. This was not a high-end trip. Instead it was a road trip to some of the lesser visited sights and it was during a period that was unexpectedly dry. I was particularly interested in the survivability of two well recognized cat species. The lions and cheetahs are two very different genus of predatory cat species at the apex of the food chain.

VOCABULARY

The vocabulary in these post also include several technical terms that apply to our discussion. For definitions, follow their links. Genetic drift, founder effect, gradualism, saltation, adaptive introgression and hybridization.

A close-up of a cheetah licking its lips with a blurred grassy background.
Fig 1. A distinction of genus is the outstanding characteristic to be followed in this series. Cheetah are from the genus Acinonyx while Lions are of the genus Panthera. They are not genetically related.

Let’s look at the driving forces and their results. The following charts show the approximate location of the Great Rift Valley region in Southeast Africa. This is a massive geologic event which is actively happening as we watch. The continent is splitting the eastern quarter of the continent off the main body. This gigantic split has created a huge valley that will someday be filled with ocean. It is accompanied by volcanoes, earthquakes, lava flows and uplifting plateaus.

GLACIAL REBOUND

From the last two glacial periods, 21,000 and 13,000 years ago, the continents are still recovering. The ice pack at the poles still hold the last remnants of that ice age. One result of this diminishing ice can be seen in the African desertification. The Sahara and Kalahari deserts are the result of the last ice age. When the poles melt and the Rift Valley floods the main portion of the African continent will recover. The deserts will bloom and the chronic drought in Africa will be concluded. The new continent will be created east of the Rift Valley. Migration may reverse. It just takes time. Never-the-less, the adaptable survivors will prevail.

Vast desert landscape featuring a rocky outcrop with vegetation atop, surrounded by dry, arid terrain and distant hills.
Fig.2 Olduvai Gorge in Tanzania, the Louis Leakey campsite, desert landscape

ECOLOGIC BARRIERS

As a result of the climatic changes, geographic barriers emerged. These are called Walls and they divide Africa into three eco regions.

These include the Saharan desert, the sub Sahil West-Africa separated from the Sahara by the line called the wall called the Sahil and East-Africa with Great Rift Valley, Fig.4, separated from wast Africa by the Great Wall of mountains.

The Great Walls of Africa limit the direction of animal migration and isolate the wildlife. This isolation has a double effect on all life forms by promoting speciation but also risking the compromises of genetic drift. In Fig. 5 the Sahil, shown as a green line, is the wall created by the Sahara. The Great Wall of mountains shown as blue line of Fig.5 parallels the Great Rift valley. Note that the regions of Kenya and Tanzania, Fig. 6 outlined in blue, are in high arid, desert risk locales.

MIGRATION

Through the two Great Walls there are narrow gaps called “bottle necks” . These geographic locations limit commingling and migration of species. These are the few areas through which animals can migrate. Except for the Nile river flowing through the Great Rift valley none of these areas follow the seasonal north-south wet weather patterns nor a river flow to another land mass. The access to Eurasia from the generative basis of Africa is through the three bottle necks of the Straights of Gibraltar, the Nile river delta and the Straight of Bab Al Mandeb. During the last 12,000 years the shallow Nile river delta crossing has been the least treacherous.

Mov. 1 Wildebeest migrating northward following the water and new grass. Lions, Cheetah and other predators follow the prey.

The illustration Fig. 7 is a conceptualization of the most direct routes for migration. Interestingly the Great Migration for animals from Africa also follows the projected route for hominoid migration. Mov.1.

Map of the Great Rift Valley and its geological features, including the Eastern Rift, Western Rift, and surrounding plates in East Africa.
Fig. 4 Location of the Great Rift Valley shown as the purple area in the red bracket. The insert shows the tectonic plats promoting the rift.
Map of Africa with highlighted Nile River, showing elevation variations in the southern region.
Fig. 5 The Great Wall of mountains and volcanoes west of the Rift are marked in the blue bracket. The Sahil marked in green, is the sub Saharan line south of the desert. The Great Wall and the Sahil are Africa’s migration barriers.
Map of Africa showing different risk levels for a specific factor, with regions colored in green, yellow, orange, red, and gray, indicating low to very high risk.
Fig. 6 Sub Sahil desertification is below the Sahara and is a high risk for drought. The light blue outline defines the Great Migration area. This area is at moderate drought risk.

The illustrated route could be followed in both directions as driven by climate change and the paths of migration of predated species sought after by the apex predators. As the glaciation advanced or retreated these routes would have water which would support grasses, insects, herbivores and carnivores. The Nile is the only north /south river. It flows to the Mediterranean through the Great Rift valley. Following the Valley waterway this leads to the choke points to the Eurasian continents. Following the east west routes of the Congo River, the Niger River or the Zambezi River leads to migration potential but dead ends at the two vast oceans.

Map of Africa showing various river basins highlighted in different colors, with a prominent pink line indicating a geographical feature.
Fig. 7 This is a conceptualized path for the bidirectional migration routes shown in red overlying a map of Africa.

We will follow two cat species which are the result of adaptations after the last Glaciation period. Panthera contains the largest number and variety of living members of the cat family. There are five living species: the jaguar, leopard, lion, snow leopard and tiger. It contains the five living species of “big cats” capable of roaring. Cheetahs belong to a completely different biological genus (Acinonyx).  They cannot roar, have distinctly different anatomy, including semi-retractable claws for high-speed traction and a unique, lightweight skeleton

A collage depicting six types of lions with labeled names: Transvaal Lion, Congo Lion, West African Lion, Nubian Lion, Southwest African Lion, and Asiatic Lion.
Fig. 8 Gross view of lion subspecies
An infographic displaying the four living cheetah subspecies: Southern African cheetah, Northeast African cheetah, Saharan cheetah, and Asiatic cheetah, along with their scientific names, distribution areas, and conservation statuses.
Fig. 9 Gross overview of cheetah subspecies

Continue to follow this amazing story of Earth changing forces. See the combination of struggle, adaptation and survival of life that sweeps across the planet through hundreds of thousands of years. Learn about the unique capabilities and risks to the Cheetah and the Lions. Because we are part of this great drama, you may use this knowledge to anticipate our future.

All photographs created by John Knapp

References:

Mitogenomic analysis of the genus Panthera

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Antelope Species of Botswana and Kenya

The antelope species make up the vast majority of Africaโ€™s wild mammal population.* There are millions of them grazing across the land. They are vegetarian. Grazing animals consume the annual growth of the Savana and woodlands. They trim the grass, shrubs and trees. They are prey for the carnivores and spread the seeds of the plants. They are an integral part of this great ecosystem.

The feature image is a magnificent male Greater Kudu in a forested area of the Okavango Delta

These animals are part of an animal clade called Ungulates(**) because of their toes with hooves. The ungulates also have horns that are bilaterally symmetric without branches but with variations such as twists, spirals, rings and flutes. These appendages are bone covered with keratin. They are well adapted to their coarse vegetarian diet and have a specialized digestive system which allows them to digest cellulose.

They all move together in groups because safety is in numbers. Part of that behavior includes mixing with a herd of other similar grazing animals for added protection. Included in this group are Gazelle, Bushbuck, Waterbuck, Eland, Reedbuck, Gerenuk, Dik-dik, Kudu (lesser & greater), Wildebeest, Ayala, Bongo, Oryx and Impala.

My first introduction to the antelopes was a charmer. The little doe wandered into our campsite and simply walked in front of me as if by magic. Fortunately, I had my camera and like it was by plan she waited and posed for me for this portraits.

Cape Bush Buck faun. This animal is usually shy but will become habituated to humans and stay near the lodge. A real cutie!

These animals had the most interesting behaviors, colors and horns. I found the Impala to be the most beautiful. They have such large eyes and their coats are gorgeous; so shiny and without any blemishes. The distinctive markings on their rumps are narrow vertical black stripes. They are also very busy. Unlike the big cats, they are always involved in some activity. Since they are grazers they eat the low grasses. This unfortunately distracts their attention and they canโ€™t look up for dangerous prey like lions or dogs. Therefore, when you see them, there is a rotation of grazers and sentinels with their heads up. When they are chased or pursued they are extraordinarily fast and agile. When fighting for dominance in their herd they use their horns, sometimes with deadly precision.

Female Impalas (Aephyceros melampus) in wooded area of the Okavango. Note their shorter horns compared to the males.
Two male impala dueling with interlaced horns They were probably sparing and not fighting for dominance because the males were not separated from the females. Boys! Be careful when you play with those sharp things!
Male and female Impala drinking from a small creek in Maasai Mara. These antelope were everywhere. They were probably the most numerous and sometimes they herded together in groups of 50 or more.
Hoof print of an antelope. Probably Impala. Note the “split” of the keratin hoof, showing the characteristic two toes. (***)
Impala and Lesser Kudu sharing space at the riverside in Chobe National Park, Okavango, Botswana. Check out the Impala scouting the background.

Perhaps one of the remarkable features of the giant Kudu antelopes was their spiral horns. Spiraled but nearly straight, the antlers of the Kudu were the most distinguished. The white stripes of their coats were also easily recognizable.

Greater Kudo, (Tragelaphus strepsiceros) with beautifully spiraled horns
Greater Kudu mixed with a herd of Zebra in the marshland of Okavango Delta of Botswana. It was easy to identify these large animals. Birds on the bodies of the Kudu eat the insects that are a pest for the large mammal.
Tsessebe are sometimes called the “Blue Jeans antelope” because of its distinctive leg coloration.
Lechwe (Kobus leche) Standing in front of our tent in late afternoon.

During a game drive through the shallow swamp the water buck obliged us with his massive ringed horns.

Water buck (Kobus ellipsiprymnus) In the Okavango Delta marsh.

If our guide had not pointed it out I would have easily missed seeing the Dik-dik. It is so small and blends so easily with the ground color that it was almost invisible. It was smaller than the tiny doe that visited the camp site on another occasion.

Dik-dik (Madoqua kirkii) Smallest of the antelope species is only18 inches tall.
Gerenuk (Litocranius walleri) standing on its hind legs eating leaves. This is a typical behavior.
Oryx (Oryx beisa) Long straight ringed horns and painted face are signature trademarks for this large animal.
Thompson’s Gazelle (Eudorcas thompsonii) Straight horns with rings dark band along the lateral aspect of the ribcage. Smaller than the Impala and the Grant’s gazelle. Almost as fast as a cheetah and very numerous.
Grant’s Gazelle (Gazella granti) (Nanger granti) White rump, straight horns and black facial patches. Beautiful dramatic evening lighting.
Hartebeest (AKA Kongoni) (Alcelaphus buselaphus) This is a very rare finding because this animal is facing imminent extinction. A five party group of them was grazing in the Maasai Mara.
Roan antelope (Hippotragus equinus). One of the largest of the antelope with a roan color or a reddish-brown coat.
Wildebeest (Connabaetes taurines). We have previously posted on this species of antelope and the Great Migration.

Along with the general mix of the population, the antelope species have an important and sometimes grim role in the African landscape. They are the object of the predators. We have already reviewed the predators of this region. Check out our blog site that describes the wild dogs of Africa.

References:

* Uganda antelope

** What is an ungulate?

*** African Animal Tracks

#antelope #Gazelle #Bushbuck #Waterbuck #Gerenuk, #Dik-dik #Kudu #Wildebeest #Oryx #Impala #Africa #Botswana #Okavango #Kenya #Maasai Mara #horns #hoof #ungulates

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The African Great Migration and Its Significance

The last few days of our expedition gave meaning to our adventure. We were in the Kenyan Maasai Mara, thrilled by the larges animal migration of on Earth.

On the cover photo is a group of blue Wildebeest. AKA the common wildebeest Connochaetes taurinus) it is a large antelope found in Kenya and Tanzania.

One wildebeest is not photogenic. There is never just one. Tens of thousands of them live and move together as one massive organism. Hundreds of thousands of mixed species of animals move with them and between each other during the great wildebeest migration.
Migration map We were in the Maasai Mara during the last four days of August.

The Maasai Mara of Kenya is contiguous with the planes of the Serengeti National Park and the Tanzanian National Park. All are part of the Serengeti plane. These images are from the Kenyan Maasai Mara National Reserve. It was the most favorable point to observe the Great Migration when we were there. As the weather changes from dry to the rainy season the grass regrows. It is the grass which provides food for the grazing animals. This is irresistible to the wildebeest, zebra, impala, buffalo and other animals who follow this growth by the millions. The dead grass remains after the tops have been eaten to the ground or burned off. The rain brings a fresh regrowth. This regrowth replaces the razor-sharp stubble with soft young plants.

One of the most thrilling wildlife spectacles on earth was spread before us like pepper on a salad. We stopped to watch this ancient migration sight that this area supports. You can see in every direction that the savanna is covered by hundreds of thousands of animals. It is hard to comprehend that they actually number in the millions. They are visible to every horizon, slowly moving to follow the fresh growth. They meander about eating and mingling, occasionally fighting and challenging one another for mating or protecting one another from the daily challenges of survival, reproduction, and predation. For reasons unknown to us they may gallop along following some instinct or stamped when startled or frightened. It is this cumulative picture of integrated behavior based on soil, seasonal weather, prolific plant life and a massive accumulation of thousands of animal species which underscores the interdependency of this huge ecosystem.

Migrating animals wandering from one side of the horizon to the other. View of the north.

We did cross the Mara river and its tributaries where crocodiles and hippopotamuses were swimming or simply resting. The hungry crocodiles were ready at a wildebeest crossing to take advantage of the weakest or most vulnerable animals. We did not see this classical behavior but none-the-less the trap was set. Predators and scavenger animals follow this migration in the ladder of primacy with the lion at the apex.

The Mara river teeming with crocodiles waiting for the stampede.
The blue wildebeest, keystone animal of the Serengeti, Maasai Mara. Running with the group on its way into the future.

The wildebeest is the keystone animal of this ecosystem. It is the primary consumer of the grasses. It has a high reproductive rate. It is the resource upon which all of the carnivores and scavengers depend. They till and fertilize the soil. A single calf is born after 8.5-month gestation. Bands of female wildebeests are in control, leading the entire herd towards new grasslands. In the mid-20th century, the wildebeest population was decimated. The herd was cut down to one third of its normal size because of the rinderpest viruses (a variant of the measles virus). It originated and was spread from domestic livestock. As a result of loss of the grazing animals the grass lands grew uncontrolled. This over-growth subsequently changed the natural fire regime to an intense wildfire which burned nearly the entire Serengeti. This was an ecological disaster. Millions of domestic animals also died. Plant and animal species collapsed. Because of a massive human intervention including vaccination and quarantine the wildebeest population has been transformed. The Serengeti and Maasai Mara have been magnificently rewilded and the population of these animals is back to a stable 1.5 M with no disease detected in the last 8 years. Perhaps my 30 year wait to go was helpful because it allowed the wilderness more time to recover.

View to the south where the spread of animals seems endless.
Mixed wildebeest with zebra was a common observation
Animals on the move for the last hour and will probably continue for the next hour (My first video)

The sight of all these animals and the resource to feed and accommodate all of them provides a small but expanding view of the might of the ecosystem. At one time in the distant past this view would have been quite prosaic. Imagine Neanderthal or possibly the older Cro-Magnon people living with this type of annual migration. They would have been part of it. They would have been much earlier than our current view of history, but it probably looked like the American Great Basin to the First Peoples and early settlers of the Americas. We must appreciate that this area is just a few hundreds of miles from the Olduvei (Oldupai) gorge where Lewis and Mary Leakey (beginning in 1937) found fossilized hominoid remains dating back hundreds of thousands of years. (Pronconsul 25 million years old).  What were those people thinking when they saw this sight? The ancient hominoids and modern tribal peoples were and still are intimately connected with this environment. Their moment-to-moment survivals depended upon understanding this grand recipe and also the small, intimate details of their surroundings. The people of the Maasai tribe move their domesticated herds in synchrony with the wildlife, plants and rainfall. They know this because of their exposure to a multigenerational experience. They now participate in separation of their herds of domestic cattle and vaccination from Rinderpest and Foot and Mouth disease. We were so poorly prepared to comprehend systems as complex as this in just a few days.

I think that there are many lessons to be learned from this. For at least a million years hominoids and humans have learned that living in harmony with the constantly changing environment is a prerequisite to survival. The environment changes including geologic-like continental drift and volcanism. Weather changes, due to wind and rain/snow, land slides and floods, drought, temperature and storms. Species changes with mutations and natural selection. Human behavioral changes including perception and interpretation of surroundings, the value of group behavior and behavioral adaptation by creation of societies. Society changes with development of institutions like religion and governments. Behavior changes lead to exploration, discovery, invention and industrialization. The nomadic herders of today who live in near Stone Age conditions with cell phones will change. What changes will Space Age people make? We, the people of the space, information and atomic age have the ability to affect all of the aforementioned changes. We have the opportunity to do so because we live with disposable wealth and a discretionally directed time.

From the successful story of the rewilding of wildebeests in the Serengeti we have started on a new path. The wildebeest story is considered one of the most successful rewildings of our time. Rewilding efforts have been remarkably successful in Yellowstone, Spain, Argentina, Switzerland, ocean reef areas and many more. These efforts can not only save species and restore habitats but also fight the climate change crisis. Rewinding Florida is an active effort and a topic worthy of further exploration and discussion.

#Africa #wildebeest #Great Migration #migration #Maasai Mara. #Serengeti #rewilding #Mara river #stampede

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