Monday, October 21, 2024

Creation Moment 10/22/2024 - Glycolysis

Thank you for making me so wonderfully complex! 
Psalm 139:14

"The purpose of cellular respiration is to convert the energy stored in glucose into
adenosine triphosphate (ATP), the primary energy currency of the cell. 

Cellular respiration occurs in three main stages. 
--Glycolysis involves the breakdown of glucose into pyruvate, producing a small amount of ATP
--The citric acid cycle further breaks down pyruvate into carbon dioxide, generating NADH and FADH2. 
--The final step of cellular respiration is the electron transport chain and oxidative phosphorylation, which produce a large amount of ATP, as well as water as a byproduct. 

Glycolysis is ubiquitous across all living organisms.....glycolysis
involves the conversion of glucose, through a series of intermediates, to pyruvate. 
---This pyruvate is then transported into the mitochondria where it is converted into acetyl-CoA by the enzyme pyruvate dehydrogenase. 
---This process also produces NADH and releases one molecule of carbon dioxide (CO2). 
---The acetyl-CoA then feeds into the citric acid cycle, where it is further oxidized, generating more NADH, FADH2, and ATP (or GTP).

Q: Incremental Evolution?
Glycolysis has been proposed to be the first biochemical pathway to arise in evolution. Among the reasons for this are the fact that glycolysis is found ubiquitously across the tree of life (so may be inferred to have been present in the last universal common ancestor). Moreover, glycolysis is an anaerobic reaction sequence, and thus is consistent with the absence of oxygen in the primitive Earth environment.

*There are, however, significant challenges to a proposed evolutionary origin of the glycolysis pathway. 
For example, the conversion of glucose to pyruvate involves as many as ten independent enzymes, typically 300 to 500 amino acids in length. 
It is extremely implausible that ten enzymes with complementary activities could have arisen at essentially the same time. 
Q:  But could the pathway have evolved incrementally, either forwards or backwards? 
It is generally rejected that glycolysis arose backwards (i.e., with pyruvate being initially available, then its precursor, etc.) since it was not the oxidized pyruvate, but rather sugar, that would have been present in the early Earth environment. Moreover, every intermediate between glycose and pyruvate is phosphorylated (i.e., has one or two of its hydroxyl groups replaced by phosphate). This involves a condensation reaction (where a water molecule is eliminated). 
---Given the difficulties of this type of reaction, it is questionable whether the various intermediates could have emerged abiotically in high enough quantities to facilitate the origin of glycolysis.

The more popular view is that glycolysis evolved incrementally in the forwards direction. This hypothesis, of course, relies on the presumption that the intermediates could have served their own independent utility. 
However, since glycolysis is generally thought to have arisen extremely early — before additional utility of the intermediates could have arisen — it seems unlikely that the intermediates could have had independent usages.

Causal Circularity
Notice that the process of glycolysis consumes two ATP molecules — one at the glucose to glucose 6-phosphate step (catalyzed by hexokinase) and one at the fructose 6-phosphate to fructose 1,6-bisphosphate step (catalyzed by phosphofructokinase). 
---The overall ATP yield of glycolysis is four (although many more ATPs will be produced later on), while two are consumed — making the net yield two ATPs
In order for ATP to be produced, ATP must first be consumed. 
This presents a causal circularity challenge to an evolutionary account of the origins of glycolysis
Strikingly, this causal circularity of ATP being required to manufacture more ATP appears to be ubiquitous across life. 
Q: How could the process of glycolysis be established without an initial supply of ATP
Moreover, after the consumption of the first ATP, there are at least five additional steps (each involving its own enzyme) before any further ATP is produced), and nine before there is a net yield of ATP. Given that natural selection lacks foresight, this renders it extremely implausible that the enzymes early on in the glycolytic pathway could have served any benefit in the absence of the enzymes later in the pathway.

Excluding Water
Of the ten enzymes involved in glycolysis, six catalyze reactions that involve a phosphate group transfer. For a phosphate to react with a hydroxyl group of water to form phosphoric acid is just as energetically favorable as for it to react with the hydroxyl or a sugar or ADP. 
But this would be of no evolutionary advantage. 
Thus, water must be excluded from the enzymes’ active sites to prevent hydrolytic reactions from occurring. 
This is achieved through a mechanism involving conformational changes that resemble a “hinge motion.” Initially, the enzyme’s active site assumes an open conformation, allowing the substrate to enter. 
---When the substrate binds to the active site, it induces a conformational change, causing the enzyme to undergo a “closing” motion, with the domains of the enzyme coming together, effectively shielding the active site. This motion not only secures the substrate but also excludes water from entering the active site.

This phenomenon underscores the engineering sophistication and the degree of amino acid specificity of these enzymes. Since the exclusion of water is absolutely critical to the occurrence of the appropriate reactions, there would be no use in having a partly formed enzyme (i.e., one that could catalyze the phosphorylation reaction but failed to exclude water). This casts further doubt on the ability of incremental adaptations to account for the glycolytic pathway.

Multiple challenges confront an explanation of the glycolytic pathway in terms of unguided evolutionary mechanisms. 
The complexity and engineering sophistication comport much better with the hypothesis of design. 
In particular, the causal circularity of ATP being required to make more ATP is difficult to account for by a stepwise evolutionary process. On the other hand, this sort of phenomenon is totally unsurprising on the supposition of the involvement of an intelligent mind.
EN&V