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Wednesday, 30 June 2021

Information a necessity for biochemistry?

 

Just Down the Street from ID: “Molecular Assembly Index”

Paul Nelson

This is just down the street from intelligent design. From a paper, “Identifying molecules as biosignatures with assembly theory and mass spectrometry,” in Nature Communications (open access):

…we hypothesized that the very complex molecules made in any biochemical system could be distinguished from those produced in a non-biochemical system. This is because living systems appear to be uniquely able to produce a large abundance of complex molecules that are inaccessible to abiotic systems, where the number of small organic molecules, allowed by the rules of chemistry, is practically infinite.

The argument continues (emphasis added):

For example, the natural product Taxol, is an example of a molecule that could be a biosignature — this is because it is so complicated, that the probability of its formation abiotically in any detectable abundance (>10,000 identical copies) would be very small. One reason for this is that there are at least more than 10exp23 different molecules possible with the same formula as Taxol, C47H51NO14 (molecular weight of 853.9), and this analysis excludes the fact that Taxol incorporates 11 chiral centers which means it has 211 or 2048 possible diastereomers. The selection of one such possibility out of the combinatorically large number of possibilities is a process that requires information. In the absence of such information encoding and decoding processes, relatively few constraints can be placed on a chemical system — only those that are encoded in the laws of physics and the local environment — which cannot provide the specific set of biases needed to produce complex molecules such as Taxol in abundance.

Their approach (emphasis added):

…we have devised a theory of molecular complexity that is experimentally verifiable. By mapping the complexity of molecular space it is possible to place molecules on a scale of complexity from those able to form abiotically to those so complex they require a vast amount of encoded information to produce their structures, which means that their abiotic formation is very unlikely.

The publication is here. Figure 1, “Assembly pathways,” is helpful.

The stones cry out.

 At one time, some Bible minimalists (those who believe the Bible is of minimal value historically) questioned the very existence of King David. In recent years, numerous archaeological discoveries have confirmed the existence of Israel’s greatest king, and affirmed numerous details in the biblical text regarding his life and the times in which he lived.  Here are the top ten discoveries related to King David.  

10. Ancient Slingshots





David is perhaps best-known for his epic mano-a-mano battle against Goliath. The boy with a sling defeated a gigantic, seasoned warrior. While many are familiar with the Y-shaped slingshots with the rubber bands that are used today, slings in the Old Testament were quite different. Biblical weapons expert, Dr. Boyd Seevers describes them: “A sling can be a simple as a strap some three feet in length and one inch in width, though it is often made with two narrow chords attached to a wider pouch in the center. Often, the sling is woven from wool or some other type of flexible material from an animal or plant. One end is looped or knotted to attach to one of the fingers of the thrower’s hand, and the other end is knotted for the thumb and forefinger to grip until the moment of release.”1 Several ancient slingshots from Egypt have survived until today, including King Tut’s sling, which was discovered in his tomb.   Slingshots were formidable long-range weapons in antiquity. Ancient texts suggest that slingers were accurate with their projectiles up to 400 yards.2 Scripture records that there were 700 men from the tribe of Benjamin who could “sling a stone at a hair and not miss.” (Judges 20:16). This gives us a better understanding of the advantage David had in his battle with Goliath. Of course, we ought not forget that the Battle belonged to the Lord (1 Sam. 17:47).

9.  The Gath Ostracon


This inscribed pottery sherd was discovered at Tell es-Safi/Gath and contains two names that are similar etymologically to the name Goliath. Photo: The Tell es-Safi/Gath Archaeological Project

In 2005, an inscribed ostracon (inscribed pottery sherd) was unearthed at Tell es-Safi (the site of the biblical Philistine city of Gath) that was dated to the Iron Age 2A period (when David and Goliath lived). The inscription, written in Semitic “Proto-Canaanite” script contained two names: ALWT and WLT.3 Both of these names (ALWT – Heb. אלות  and WLT – Heb. ולת) are very similar etymologically to the name Goliath (Heb. גלית). Aren Maeir, the director of the excavations at Tell es-Safi/Gath summaries the importance of this inscription: “1) the inscription demonstrates that ca. the 10th/9th cent. BCE, names very similar to Goliath were in use at Philistine Gath. This does provide some cultural background for the David/Goliath story; 2) that already early in Iron IIA, the Philistines adopted the Semitic writing systems.”4


8. Hebron (Tell Hebron/Tell



David initially reigned as king of Judah at Hebron, while Saul’s son Ish-Bosheth, reigned as king of Israel from Mahanaim. (2 Sam. 2:8-11). Hebron has identified as Jebel er-Rumeide, also called Tell Rumeide or Tell Hebron. Five LMLK (to the king) jar handles bearing the city name Hebron have been discovered at the site.5 Excavations have uncovered sections of the Middle Bronze II city wall, which continued to be used in the Iron I and II periods,6 as well as the remains of four-roomed houses and fragments of collared-rim jars, both of which are typically associated with Israelites. The remains of David’s royal residence likely lie on the summit of the tell, which is covered by a medieval structure (called Deir Arbain by the locals) which was originally a Byzantine monastery, and is off-limits to excavation.8 While David is more commonly associated with Jerusalem, the first capital of the Kingdom of Judah was at Hebron.


7. Geshur (et-Tell)



While David was reigning in Hebron, he had numerous sons by various wives. His thirdborn was Absalom the son of Maacah daughter of Talmai king of Geshur (2 Sam. 3:3). Later, after Absalom had murdered his brother Amnon, he fled to his grandfather, Talmai, son of Ammihud, the king of Geshur, and lived with him for three years (2 Sam.  13:37-38). Scholars have suggested that David married Maacah, the daughter of the king of Geshur to solidify relations between their two kingdoms, and to strengthen his own position.  In antiquity, the usual practice was for the daughter of the more powerful ruler to be given to the weaker ruler, which would indicate that Geshur was the stronger kingdom.9

Et-Tell, a site 3km (1.5 miles) from the north-east shore of the Sea of Galilee has been identified as the capital of the Kingdom of Geshur. It satisfies the geographic criteria in Scripture (Deut 3:14; Josh 12:4–5; 13: 11–13), where it often paired with Abel Beth Maacah. Abel Beth Maacah is identified as Tell Abil al-Qamh, and et-Tell is identified as the capital of the kingdom of Geshur; both sites are the most prominent Iron Age mounds in the region.10 Et-Tell (one of the contending sites for New Testament Bethsaida), was a significant fortified city in David’s day; the massive four–chamber Iron-Age Gate can still be seen today. A carved basalt stone stela was discovered near the city gates and depicts a bull-headed figure, which likely represents either the storm god or the moon god the people of Geshur worshiped.11 If the identification of et-Tell as the capital of the kingdom of Geshur is correct, then this is likely where David’s wife Macaah was from, and the place his son Absalom lived for three years.

6. Large Stone Structure (King David’s Palace in Jerusalem)



David was eventually made king over all Israel (2 Sam. 5:3), and he immediately captured Jerusalem (2 Sam. 5:7), and set to budling a palace, which Hiram, king of Tyre, assisted in the construction of by providing cedar logs, carpenters, and stonemasons (2 Sam. 5:11). From 2005-2007, Israeli archaeologist, Dr. Eilat Mazar, unearthed what is now known as the Large Stone Structure, a monumental building complex with walls that were 6-8 feet wide, constructed of impressive stones, and to which a beautiful 5-foot-long proto-Aeolic capital likely once belonged. It is located above the famous Iron-Age Stepped-Stone Structure, which probably supported the Fortress of Zion and the Large Stone Structure above. The pottery found beneath the Large Stone Structure, dated the first phase of its construction to the beginning of the Iron Age IIa (10th century BC), the time of King David. Based on the palatial nature of the structure and the fact that its location matched biblical data (such as 2 Sam. 5:17 – David descending from his residence to the fortress), Mazar identified the structure as David’s Palace.12 While this identification has not been without controversy, numerous scholars accept her conclusion. Archaeologist, Dr. Scott Stripling, states, “Eilat Mazar’s excavation of the Large Stone Structure likely revealed David’s actual palace, just above the well-known Stepped Stone Structure or milo.”13 Nadav Na’aman, former professor of Jewish History at Tel Aviv University notes, “The Large Stone Structure, which Eilat Mazar unearthed and identified as the residence of King David, is indeed a suitable candidate for this building, or more accurately, for its northeastern wing.”14






5. Judahite Cities (Khirbet Qieyafa and Tel Eton)


Scripture records David’s kingdom expanding (2 Sam. 8:1-4), and controlling the kingdom from his capital city of Jerusalem. Two fortified sites dating to the 10th century have been unearthed which scholars believe are evidence of such a centralized authority Yosef Garfinkel (Hebrew University) and Saar Ganor (Israel Antiquities Authority) oversaw excavations at Khirbet Qeiyafa from 2007-2013. The site is located 30km southwest of Jerusalem, within the kingdom of Judah, and surrounded by a massive casement fortification wall with two gates. Its 10th century date was confirmed by radiocarbon dating of pits in a destruction layer of a large royal storeroom.15 The excavators identified it as a Judahite outpost based on inscriptional evidence (an ostracon with one of the earliest Hebrew texts yet found), a lack of pig bones, and the presence of cultic shrines that did not have any graven images of people or animals. Garfinkel and Ganor state, “The massive construction of the Khirbet Qeiyafa city wall, which required 200,000 tons of stone, and the massive eastern gate of the city with two stones of ca. 10 tons each, proclaim the power and authority of a centralize political organization, namely a state.”16controlling the Archaeologists from Bar-Ilan University recently excavated El Eton, another site that dates to the time of David and displays evidence of a strong, central political administration during its construction. A monumental structure, dubbed the “governor’s residency” was built using quality ashlar stones in the typical Israelite four-room design. Radiocarbon dating of samples taken from the foundation deposit indicate that the earliest phase of the structure was built in the late 11th-10th century BC. In an article in the journal Radiocarbon, Avraham Faust and Yair Sapir wrote: “The building of the ‘governor’s residency,’…suggests that the settlement at Tel ‘Eton was transformed in the 10th century BCE, lending important support to the historicity of the United Monarchy…[it] exhibits the earliest evidence for the use of ashlar stones in the region of Judah, and the mere erection of this edifice challenges one of the arguments against the historical plausibility of the United Monarchy (i.e., that ashlar construction appeared hundreds of years later).”17



4. Davidic Kings




After King David’s death, 20 of his descendants ruled in succession after him, from Solomon to the kings who reigned over the southern Kingdom of Judah. Archaeology has furnished numerous finds attesting to many of these Davidic kings.18 The nearly identical gates at Hazor, Megiddo, and Gezer are evidence of Solomon’s building activity as described in 1 Kings 9:15.19 Ahaziah is the king of the “house of David” referred to on the Tel Dan Stele (see below). Two seals which once belonged to officials in King Uzziah’s court mention him by name. A bulla (clay seal impressions) that reads, “Belonging to Ahaz (son of) Yehotam [Jotham], King of Judah” is held in the private collection of Shlomo Moussaieff in London. Numerous seal impressions from King Hezekiah have been discovered, and he is named in the annals of Sennacherib. Manasseh is named in the annals of both Esarhaddon and Ashurbanipal, while Jehoiachin is mentioned in ration tablets from Babylon. Each of these discoveries independently corroborates the biblical description of a Davidic line of kings who reigned in Israel and Judah for generations.


3. “Heights of David” Inscription



King David’s name has been found in numerous ancient Inscriptions, including one possible reference from Egypt. When the Egyptian Pharaoh Shishak (Shoshenq I), returned from his campaign in Palestine in 926/25 BC, he commanded that his victories be recorded on the walls of the Temple of Amun in Karnak. More than 150 hieroglyphic name-rings, each represented as a bound prisoner, are recorded on Bubastite Portal detailing the places he conquered during his northern campaign. Names rings 105 and 106 together read h(y)dbt dwt – the “Heights or Highlands of Dawit.” Egyptologist, Kenneth Kitchen, has proposed that this should read, “Heights of David.” He writes, “In Egyptian transcriptions of foreign names (both places and personal), a t could and sometimes did transcribe a Semitic d. This happens in the New Kingdom in such familiar place-names as Megiddo (Egyp. Mkt).”20 He further points to a sixth century Ethiopic inscription citing Psalm 65:19 from the “Psalms of Dawit,” the exact consonants on the Shishak Inscription. Kitchen summarizes: “This would give us a place name that commemorated David in the Negev barely fifty years after his death, within living memory of the man.”21 His conclusion is not without its critics, however, as some have suggested that ring 106 is difficult to decipher and may not read Dawit at all, let alone reference David.  

2. Mesha Stele (Moabite Stone)



The famous Meshe Stele (Moabite Stone) consists of 57 fragments which were purchased from bedouin in the 19th century, and assembled, along with a squeeze of the inscription which had been taken before the monument was broken. The stele, a black basalt monument measuring 1.5m (45.28”) high by 60-80cm (23.6-31.5”) wide, is a victory stele of Mesha, king of Moab. Written in Moabite, it describes the same events in 2 Kings 3, Moab’s rebellion against Israelite subjection. In 1994, epigrapher, André Lemaire announced that he had detected a previously-overlooked letter, resulting in the phrase, “House of David.” He wrote: My own examination of the stone and the squeeze, which is now being restored and cleaned of accumulated dust, confirms that follows the b. I would now, for the first time, reconstruct the missing letter as a d (d). The result: bt[d]wd (dw[d]tb), the “House of [D]avid!”22 The relavent part of the inscription reads, “And the house[of Da]vid dwelt in Horanaim […] and Chemosh said to me: ‘Go down! Fight against Horanaim.’ And I went down, and [I fought against the town, and I took it and] Chemosh [resto]red it in my days” (lines 31-33).23 In 2019, the Mesha Stele hit the news again when Israel Finkelstein, Nadav Na’aman, and Thomas Römer published a paper in the Journal of the Institute of Archaeology of Tel Aviv University analyzeing Line 31 on the Moabite Stone arguing the words in question refer to Balak, not the “House of David.”24 Scholar, Michael Langlois, responded with an analysis published in the Journal Semitica, which high resolution images and Polynomial Texture Mapping (PTM) of the stele to create a 3-D image. The new technology revealed a previously overlooked dot, indicating a break between words, which comes exactly after the area interpreted “House of David,” confirming Lemaire’s initial reading.25










1. Tel Dan Stele


The most significant artifact related to King David is most certainly the Tel Dan Stela. In 1993, archaeologists at Tel Dan unearthed a fragment of a monument (Fragment A), found in secondary use in the remains of a wall on the eastern section of a large pavement at the entrance to the city gate.26 The next year two more fragments from the same monument were discovered (Fragment B). The fragments belong to a victory stele recording the expoits of the King of Aram (likely Hazael, although his name is not given) over the King of Israel, and his ally, the king of the “House of David.” It dates to the ninth century B.C., about 200 years after David’s rule. Avraham Biran and Joseph Naveh, who published the Aramaic inscription, translated the relevant lines as: “[I killed Jo]ram son of [Ahab] king of Israel, and [I] killed [Ahaz]iahu son of [Jehoram kin-]g of the House of David.”27 Archaeologist, Dr. Bryant Wood explains the historical context of the Tel Dan Stele: “It was most likely erected following Hazael’s defeat of Joram and Ahaziah at Ramoth Gilead in ca. 841 BC (2 Kgs 8:28–29). The occasion for the breaking of the stela was probably when Jehoash, king of Israel from 798 to 782, recaptured Israelite territory previously taken by Hazael (2 Kgs 13:24–25). It appears that the monument stood in Dan near the city gate for over four decades. It was a constant reminder to the Israelites that they were subject to the Arameans.”28 The Tel Dan Stele establishes the historicity of King David, affirms the biblical description of his dynasty, and is a stunning rebuke to minimalists who once thought Israel’s greatest king was no more than a mythical figure created by much later writers to give Israel a glorious backstory.








The gold standard

 

 

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Yet more primeval tech vs. Darwin.

 







Cilium and Intraflagellar Transport: More Irreducibly Complex than Ever

Evolution News DiscoveryCSC

Michael Behe’s introduction of irreducibly complex (IC) molecular machines in Darwin’s Black Box is a gift that keeps on giving. Many readers probably had never heard of cilia or flagella back in 1996. The fact that those machines still make useful illustrations of IC now, even more powerfully than they did 25 years ago, is a strong affirmation of his thesis that IC gives evidence of intelligent design. The bacterial flagellum tends to get more mentions because it is such a cool outboard motor that laypersons can immediately relate to. No less wondrous, though a little more obscure, is the cilium. 

Behe updated his description the cilium in his second book, The Edge of Evolution (2007), but research has continued apace. The cilium nails the case for intelligent design more than ever, especially when considering how the organelle is built. Inside those tiny hairlike projections is an advanced transportation system that looks for all the world like a motorized two-way railcar inside a mine shaft!

In Current Biology, Gaia Pigino wrote a “Primer” on Intraflagellar Transport (IFT). It’s called intraflagellar because a cilium is a type of flagellum (Latin for whip), which in the generic sense means a whiplike structure that can move. Both cilia and flagella use the IFT system for construction because both need to transport their building blocks down a shaft from the base to the distal tip. From the railcar’s perspective, the tip would seem a long way away.

There are motile cilia, like the ones that keep our windpipes clean and propel sperm cells, and “primary” cilia, which act as sensory antennae on almost all cells. Accurate construction of cilia is vital. When things go wrong, a host of problems called ciliopathies can result in severe diseases and death. Evolution News has mentioned these briefly in previous years (herehere, and here).

Parts List

Consider first how many players are needed to build a cilium. Pigino’s parts list begins with microtubules in a 9+2 arrangement going up the cilium from base to tip. The two center microtubules are singlets; the outer ring of 9 are in doublet pairs. Riding on those rails are two engines: kinesin-2, which travels from base to tip (anterograde), and dynein-2, which goes from tip back to the base. Kinesin-2 has a head, stalk, hinge and two “feet” (called heads) that walk on the microtubule while carrying a load; the engine contains six protein subunits. Dynein-2 also has a motor, stalk, linker and tail, and is powered by two AAA+ domains that spend ATP for power. Those are the two engine types, and they work in teams along the microtubules.

IFT proteins are numbered, such as IFT8 and IFT176. IFT complexes, such as IFT-A, is composed of six IFT proteins. IFT-B, with 16 IFT proteins is another complex. These ride along the trains to the tip, acting as adaptors for the cargo, which include tubulin proteins, dynein parts, membrane proteins and other IFT proteins. 

At the base, a basal body structure called the BBSome forms out of eight BB proteins. It functions as the cargo adaptor for the anterograde train. It authenticates other molecules trying to enter the cilium and moves cargo exiting the retrograde train. Overall, “About 24 different proteins constitute the theoretical minimal functional unit of IFT,” Pigino says, although much needs to be learned.

To address the many fascinating questions that remain about the function and mechanisms of IFT within the cilium and beyond will require the development of new technologies. Fortunately, recent years have seen the introduction of approaches such as cryo-FIB scanning electron microscopy, cryo-correlative light and electron microscopy, and expansion microscopy. The opportunity to combine such approaches with in situ protein tagging for EM, isolation of active IFT complexes, and in vitro reconstitution and reactivation of IFT machinery suggests that IFT studies will continue to yield important insights long into the future. [Emphasis added.]

A precise sequence of amino acids is required for each protein’s function, and the longer the protein, the more improbable that chance could get it right. IFT proteins are large. For instance, BBS1 in the BBSome has 593 amino acid residues; IFT172 (part of the IFT-B complex) has 1,749. The improbability is exacerbated when proteins have to work together. It’s not necessary to belabor the point again, but it’s instructive that Pigino never mentions evolution in her article.

Riding the Train

Moving cargo up and down the cilium takes place in five steps. First, the train assembles at the base. Kinesins line up along a microtubule doublet, their “heads” touching the tracks. Parts of dynein (the return engine) are loaded so as not to touch the tracks, avoiding a “tug-of-war” between the engines. Membrane parts and other cargoes are loaded with the help of IFT-A and IFT-B. Like a well-organized monorail car, the completed train “walks” up the track aided by multiple kinesin-2 engines powered by ATP.

At the tip, the third phase begins. Cargo is unloaded and ferried to the growing cilium (microtubules and membrane). Concurrently, the dynein engines are assembled in an “open configuration as an intermediate state to ensure a controlled activation.” The kinesins are disassembled for transport back to the base. The fourth stage activates the dyneins and starts the train moving, carrying both IFT complexes and waste products to the base. The fifth and final stage unloads the cargo, disassembles the retrograde train and recycles the parts. If you conceive of railcars in a narrow mine shaft carrying tools needed by miners at the far end, and returning the carts with waste products, the analogy seems apt — only the cell’s actions are all automated.

It All Has to Work

Pigino spends much of her Primer discussing ciliopathies: the diseases of broken cilia. When the IFT or engine parts have mutations, or the cilium fails to develop properly, terrible things happen — really terrible things. That’s if the organism (or person) survives at all. Many ciliopathies are not witnessed because the defect causes “major issues during early embryonic development that lead to neonatal death in vertebrates.” She lists 14 known ciliopathies that cause named syndromes, like Bardet-Biedl Syndrome, which causes “rod/cone dystrophy, polydactyly, central obesity, hypogonadism, and kidney dysfunction,” or Retinitis Pigmentosa, which causes blindness. Without getting into the gory details, these ciliar defects can harm the skeleton, eyes, kidneys, brain, or multiple systems in the body at once.

Usually, It Does Work

For the majority of people born with working cilia, here is what they do for us:

Cells need to be able to sense different types of signals, such as chemical and mechanical stimuli, from the extracellular environment in order to properly function. Most eukaryotic cells sense these signals in part through a specialized hair-like organelle, the cilium, that extends from the cell body as a sort of antenna. The signaling and sensory functions of cilia are fundamental during the early stages of embryonic development, when cilia coordinate the establishment of the internal left–right asymmetry that is typical of the vertebrate body. Later, cilia continue to be required for the correct development and function of specific tissues and organs, such as the brain, heart, kidney, liver, and pancreas. Sensory cilia allow us to sense the environment that surrounds us; for instance, we see as a result of the connecting cilia of photoreceptors in our retina, we smell through the sensory cilia at the tips of our olfactory neurons, and we hear thanks to the kinocilia of our sensory hair cells. Motile cilia, which themselves have sensory functions, also work as propeller-like extensions that allow us to breathe because they keep our lungs clean, to reproduce because they propel sperm cells, and even to properly reason because they contribute to the flow of cerebrospinal fluid in our brain ventricles…. Thus, the proper function of cilia is fundamental for human health.

Professor Behe did a wonderful service in introducing these marvelous machines to a wider audience. In 1996, he introduced cilia as examples of irreducible complexity. In 2007, with a decade of new knowledge to draw from, he called cilia examples of “irreducible complexity squared.” Pigina’s Primer on cilia cannot argue with that. If you can breathe, eat, smell, taste, hear, and walk, thank the intelligent designer of cilia that makes these pleasures possible.

Monday, 28 June 2021

Heme production vs. Darwin

 




Designed for [a] Purpose” — Heme Production Defeats Evolution

Evolution News DiscoveryCSC

Hemoglobin is well known as the molecule that transfers oxygen in blood, but its precursor, heme, is lesser known. Heme is a complex molecule that looks geometrically square, with a single iron atom at the center. The heme family of metalloproteins is responsible for multiple functions in the cell and in the bodies of multicellular organisms, including humans. Our lives depend on heme. When not properly handled, though, it can be dangerous.

What Heme Does

Seven scientists (Galvin Leung et al.) from two UK universities (Leicester, Bristol) explain the significance of heme in their paper, “Unravelling the mechanisms controlling heme supply and demand,” published in PNAS. Their homage to heme is unrestrained, as is their appreciation for how the cell handles this toxic molecule.

Heme is essential for the survival of virtually all living systems and is involved in many fundamental biological processes. It is also implicated as a signaling/regulatory molecule and must be mobilized in response to cellular demands. This presents a complex logistical problem: heme cannot simply diffuse around cells because it is both insoluble and cytotoxic. We show that the cell exhibits exquisite control over release of heme by limiting its availability to one molecule or less within cellular compartments. [Emphasis added.]

Such a description should make a Darwinist shudder. How could such an “exquisite control” system evolve piecemeal? Consider just the making of heme:

Heme is essential for the survival of virtually all living systems — from bacteria, fungi, and yeast, through plants to animals. The family of heme proteins is vast, and heme proteins are responsible for a multitude of functions that are essential for the survival of the cell. To meet the needs of supply and demand for heme in cells, most organisms need to synthesize it. Biosynthesis of the heme cofactor is, therefore, one of the most important metabolic processes in biology; it occurs as an eight-step enzymatic pathway, the last three steps of which occur in the mitochondria.

It takes eight steps to synthesize one heme molecule, and virtually all life needs it — even bacteria, among the simplest of organisms. The other enzymes that construct heme had to already exist before heme could do its job. This is a serious chicken-and-egg problem for the origin of life.

Heme Synthesis

A taste of the complexity of heme synthesis can be had in “Biochemistry, Heme Synthesis,” by Ogun, Joy, and Valentine.

Heme biosynthesis starts in mitochondria with the condensation of succinyl Co-A from the citric acid cycle and an amino acid glycine. They combine to produce a key heme intermediate, 5′-aminolevulinic acid (ALA) in mitochondria catalyzed by the pyridoxal phosphate-requiring (vitamin B6) enzyme, aminolevulinic acid synthase(ALAS). This reaction is the rate-limiting step in the pathway….

That’s just for starters. Those interested in the remaining steps involved in heme synthesis can read four more paragraphs of details like these at the link above. Intermediate forms of the molecule shuttle in and out of a mitochondrion, where special gates control traffic in and out. Multiple other molecules and enzymes, including one metalloprotein containing zinc, are involved in the process. 

How could the first cell, by chance, hit on this sequence of steps that would challenge a chemistry grad student? A protocell would have needed to come up with this chemical pathway just to get heme, let alone know what to do with it once it had it. Whoops; it’s toxic, too. How many protocell tryouts died from this essential yet cytotoxic substance before figuring out that heme must be handled with care? Darwinism is dead already — but there’s more.

Heme Supply

The focus of the paper by Leung et al. in PNAS is on how cells distribute heme where it is needed without dying from it.

We suggest an exchange mechanism between protein partners to control supply and demand. Such a mechanism would provide an in-built buffering capacity for heme, enable cells to hoard supplies of heme, and protect the cell against the undesirable effects of heme.

How about that; cells know the law of supply and demand. Where did they learn that? In protocell economics class? They also know how to “hoard supplies” of heme (actually, how to maintain emergency stockpiles). In the recent pandemic, some government officials were aghast to find that emergency stockpiles of PPE (personal protective equipment), required by law, had been raided or not maintained. It led to serious shortages and drastic efforts to refill stockpiles, while patients were dying and healthcare workers were exposed to the virus without protection. Cells do not make such mistakes.

Heme Distribution

Scientists have known all about heme and its functions for decades, but few have investigated how cells distribute it where needed. This is important to know, Leung et al. explain, because “Deficiencies or excesses in cellular heme concentration also have widespread implications in health and disease” such as aging, cardiovascular disease, inflammation, and immune response. Accordingly, “there is a need to understand the logistics of heme supply and demand.” 

A cell cannot maintain a “pool” of heme to draw from, as once thought, because heme is a “nuisance” to cells. It tends form free radicals, which are dangerous, and though hydrophobic, it dimerizes in solution, making it unsuitable for delivery to proteins that only need one heme molecule per binding site. 

A free molecule of heme can therefore only exist transiently, and if a large reserve of heme is present, the heme molecules would presumably need to be exchanged rapidly between binding partners to remain solubilized, in the same way that heme is solubilized within the interior of other well-known heme proteins (e.g., hemoglobin).

The team constructed a molecular heme sensor that glows when bound to heme. In this way, they could watch the “exquisite control” system in action.

A longstanding question has been to establish the mechanisms that control the supply and demand for cellular heme. … we have developed a heme sensor … that can respond to heme availability…. The results demonstrate that concentrations are typically limited to one molecule or less within cellular compartments. These miniscule amounts of free heme are consistent with a system that sequesters the heme and is able to buffer changes in heme availability while retaining the capability to mobilize heme when and where it is needed. … This exquisite control, in which heme is made available for transfer one molecule at a time, protects the cellagainst the toxic effect of excess heme and offers a simple mechanism for heme-dependent regulation in single-molecule steps.

In effect, the cell maintains “an exchangeable (buffered) heme reservoir” that solves the availability problem while simultaneously protecting the cell from heme’s toxic effects. Free heme (the risky kind) was detected only in “a minute fraction of the entire amount of heme present in the cell” and were most likely short-lived in the process of binding to proteins.

Our experiments are thus consistent with the idea that there is a population of the total heme complement that is bound more weakly and therefore reversibly to heme-binding partner proteins or to other molecules (which might include free amino acids) that can buffer against changes in the heme concentration. … These heme molecules that are weakly bound to buffer molecules, along with the miniscule population of free heme, would constitute a body of exchangeable heme in the cell.

In their model, the buffered heme, attached to its partner, passes quickly to the enzyme or protein needing it, something like a quick pass of the ball from one player to another in basketball or football. In the cell’s game, though, there are millions of balls with millions of players passing the heme balls to the players who need it. Because the free energy of the acceptor is at a lower level, the heme is readily transferred to the acceptor, leaving the partner ready to pick up another heme. At any given time, the cell can be aware of the concentration of available heme by sensing the concentration of heme-binding partners, and supply more as the demand increases.

This exquisite control also provides a mechanism for heme-dependent signaling and regulation, as heme can be supplied discretely, leading to the switching on of proteins in single-molecule steps.

If Darwinism had been essential to their work, they surely would have mentioned it. Instead, they found a mechanism that appears (gasp! Can they say this?) designed for a purpose —

We see clear advantages of such an exchange mechanism between protein partners, designed for the purpose of managing heme supply and demand.

Overkill

To nail the case for design, consider the level of exquisite control in the next hierarchical level up. The human body makes around 250 billion red blood cells per day, and each RBC contains 270 million hemoglobin molecules, each constructed with 4 heme groups. That multiplies out to 27 billion trillion hemes per day! 

It’s amazing enough that each cell in the body orchestrates its synthesis and availability of heme. On top of that, the whole body, too, regulates the number of hemoglobin molecules and red blood cells that carry another cytotoxic substance — oxygen — from our lungs to each cell in a safe, regulated, exquisitely controlled manner. Every red-blooded person should take this to heart: we would be walking packages of explosives if it were not for mechanisms “designed for the purpose” of using energy safely for life, love, and transcendent meaning.