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Friday, October 25, 2013

Thursday, October 24, 2013

ASBMB Core Concepts in Biochemistry and Molecular Biology: Matter and Energy Transformation

Theme

Better Biochemistry
Tansey et al. (2013) have described the five core concepts in biochemistry and molecular biology. These are the fundamental concepts that all biochemistry instructors must teach and all biochemistry students must understand.

The five core concept categories are:
  1. evolution [ASBMB Core Concepts in Biochemistry and Molecular Biology: Evolution ]
  2. matter and energy transformation [ASBMB Core Concepts in Biochemistry and Molecular Biology: Matter and Energy Transformation]
  3. homeostasis [ASBMB Core Concepts in Biochemistry and Molecular Biology: Homeostasis]
  4. biological information [ASBMB Core Concepts in Biochemistry and Molecular Biology: Biological Information]
  5. macromolecular structure and function [ASBMB Core Concepts in Biochemistry and Molecular Biology: Molecular Structure and Function]
I like the idea of teaching biochemistry from a concept-driven perspective and I like the five categories. However, I was not too pleased with the description of the core concept of evolution [ASBMB Core Concepts in Biochemistry and Molecular Biology: Evolution]. It's one thing to identify the main categories but you also have to get the concepts right if you are going to advocate teaching them!

Let's see how they do with the second core concept.
Matter and Energy Transformation

The Many Forms of Energy Involved in Biological Processes

The energetics of a biological system or process—be it an ecosystem, an organism, a cell, a biochemical reaction—conforms to and is understood in terms of the fundamental laws of thermodynamics. Biological systems capture and process energy from the environment in many forms including that emanating directly from the sun (photons through photosynthesis), heat from the environment (kinetic energy), and energy rich compounds produced by geothermal processes (e.g. sulfur compounds) or other organisms (e.g. carbohydrates). Energy from all sources is chemically converted into useful chemical and physical work in a controlled and regulated fashion. The potential
energy stored in chemical bonds can used to generate motion, light, heat, and electrochemical gradients; likewise, electrochemical gradients can be used to generate motion and new chemical bonds. The input of energy from the environment allows living systems to exist in a state of nonequilibrium with their environment. The discussion of energy and matter conversions in biological systems makes use of the physical concept of changes in Gibbs free energy, or ΔG.
I think we can all agree that a basic understanding of thermodynamics is an important core concept. However, I would have worded this paragraph somewhat differently.

First, I would have mentioned that organisms can capture energy from simple inorganic compounds such as H2 or those containing Fe2+. These are energy sources for many chemoautrophic bacteria. If you are teaching biochemistry from an evolutionary perspective, it's important that students understand how these organisms capture energy. That's the process that is most like the mechanism found in the earliest living cells.1

Second, I would have put more emphasis on using captured energy in biosynthesis pathways. The paragraph mentions that energy can be used to generate new chemical bonds but that doesn't convey the importance of the process. Think about bacterial cells growing and dividing in the ocean or plants growing from a single seed. Most of the energy goes into making proteins, nucleic acids, lipids, and carbohydrates.

Third, I would drop the reference to cells being in "a state of nonequilibrium with their environment." That conceptt is covered under "homeostasis."
Catalysis

Biologically relevant energy and matter interconversions do not occur rapidly enough (often by many orders of magnitude) to support life. In living systems, biological catalysts called enzymes facilitate these reactions. Enzymes are macromolecules, usually proteins or RNA molecules with a catalytic function. Enzymes do not alter reaction equilibria; instead, they lower the activation barrier of a particular reaction so that reactions proceed much more rapidly. The presence of powerful enzymatic catalysts is one of the key conditions for life itself.

Description of the rates of enzymatic reactions represents the subdiscipline enzyme kinetics. Key concepts of kinetics, including the definitions of the terms vo, Vmax, Km, and kcat, constitute a common language for biochemists and molecular biologists in discussing the properties of enzymes.

Students should be able to apply their knowledge of basic chemical thermodynamics to biologically catalyzed systems, quantitatively model how these reactions occur, and calculate kinetic parameters from experimental data.
This is pretty good. I would only add that there are some fundamental concepts of enzyme mechanisms that need to be covered. The idea of a transition state is important. I put a lot of emphasis on oxidation-reduction reactions as a core concept in biochemistry.
Coupling Exergonic and Endergonic Processes

Biochemical systems couple energetically unfavorable reactions with energetically favorable reactions to allow for a wider variety of reactions to proceed.

Students should be able to discuss the concept of Gibbs free energy, and how to apply it to chemical transformations, be able to identify which steps of metabolic pathways are exergonic and which are endergonic and relate the energetics of the reactions to each other.
I have a problem with this section. I don't think that the concepts of "exergonic" and "endergonic" processes are very important in biochemistry and I don't use them in my textbook. They're not found in many other textbooks, either. Also, the idea of "coupled" reactions is very poorly taught in biochemistry courses. It's almost never true that enzymes simply link up two independent reactions, one of which is "favorable" and the other "unfavorable." What usually happens is that a completely new reaction is catalyzed. For example, ATP is not hydrolyzed but, instead, a group transfer reaction is created. This important concept is covered in the next section but the authors do not appear to have grasped its significance.

Not only that, what does it mean to say that a reaction is "energetically unfavorable"? Usually this refers to the standard Gibbs free energy (ΔG°′) but one of the most important concepts in biochemistry is the difference between the standard Gibbs free energy change and the actual Gibbs free energy change (ΔG) inside the cell. In most cases ΔG = 0.

It's true that there are potential "endergonic" reactions occurring inside cells. Think about ATP hydrolysis, for example. The concentration of ATP is maintained at a high level relative to ADP and Pi so the Gibbs free energy change in the direction of hydrolysis is actually more negative that even the standard Gibbs free energy change. What this means is the the reverse reaction is extremely "endergonic."

However, it is simply not true that there are steps in metabolic pathways that are "endergonic" as the authors state. That statement reflects a profound misunderstanding of a fundamental concept in biochemistry. There will not be any flux in the "forward" direction of a metabolic pathway as long as even one reaction is "endergonic." All reactions have to be near-equilibrium reactions or reactions with a negative ΔG that's maintained because the enzyme activity is regulated to prevent the reaction from reaching equilibrium.

The important concept is "flux" or flow of metabolites in one direction along a metabolic pathway. There are many pathways where flux can occur in either direction as in the central part of the gluconeogenesis/glycolysis pathway or the citric acid cycle. Students need to understand what controls flux in one direction or another. They should know that, like water, metabolic flux cannot flow uphill.
The Nature of Biological Energy

In biological systems, chemical energy is stored in molecules with high group transfer potential or strongly negative free energy of hydrolysis or decomposition. These molecules, particularly ATP, provide the free energy to drive otherwise unfavorable biochemical reactions or processes in tightly coupled and highly controlled fashion. Most frequently, the free energy needed for a process or metabolic pathway is provided by group transfer rather than by hydrolysis. In this way, efficient energy transfer is optimized, while inefficient energy transfer to the environment (in the form of heat for example) is minimized.

Students should be able to show how reactions that proceed with large negative changes in free energy can be used to render other biochemical processes more favorable.
The essence of these statements is correct but it is not explained very well. The important concept is not that you "couple" a "favorable" reaction like ATP hydrolysis to an "unfavorable" reaction like synthesis of glutamine from glutamate and ammonia (ΔG°′ = +14 kJ mol-1).
The point is that the enzyme (glutamine synthetase) catalzyes a completely different reaction—a phosphoryl group transfer reaction—with a negative standard Gibbs free energy change of ΔG°′ = −18 kJ mol-1.

[see Moran et al. (2011): Introduction to Metabolism]
If there were an enzyme that catalyzed the first reaction involving only glutamate and ammonia then this reaction could easily occur inside the cell in spite of the positive ΔG°′. It would be a near-equilibrium reaction with steady-state equilibrium concentrations of glutamate that were very much higher than the concentration of glutamine.

It's likely that the concentration of glutamine would then be too low to support all the reactions that require it. That's why the reaction involving ATP is more useful. It means that the steady-state concentration of glutamine can be maintained a much higher concentration. This requires regulation of glutamine synthetase in order to prevent the reaction from reaching equilibrium.

It seems to me that the authors (Tansey et al.) have not thought about the fundamental core concepts. They are promoting widespread misconceptions about thermodynamics and metabolism and they are missing some important concepts. I've already mentioned flux. The other missing concept is oxidation-reduction reactions (electron transfer) and the importance of reduction potentials. NADH, NADPH, and QH2 are important energy currencies inside the cell—just as important as ATP.

There's something seriously wrong with biochemistry teaching if ASBMB educators can't even correctly explain foundational concepts like "evolution" and "matter and energy transformation."


1. I believe that all introductory biochemistry students should be able to explain where chemoautrophs get their energy. If they can't do it, they haven't been taught the fundamental concepts.

Tansey, J.T., Baird, T., Cox, M.M., Fox, K.M., Knight, J., Sears, D. and Bell, E. (2013) Foundational concepts and underlying theories for majors in “biochemistry and molecular biology”. Biochem. Mol. Biol. Educ., 41:289–296. [doi: 10.1002/bmb.20727]

Wednesday, October 23, 2013

How Do the IDiots Explain the Origin of Life?

We don't know how life on Earth originated. We're not completely ignorant because we have a good idea of basic biochemistry and we know which enzymes and pathways had to be present in the earliest cells. We're pretty sure that the first life forms captured energy by oxidizing inorganic molecules. We're pretty sure that the first cells formed in the ocean.

We also know from the fossil record that the first organisms were single-celled organisms that resemble modern bacteria in size and shape. We know that they appear more than 3 billion years ago and there were no complex organisms for another billion years. We know that the idea of a primordial soup is nonsense and that speculations about an RNA world are not helpful.

Other than that, all we have is informed speculation. The correct answer to the question of how did life begin is "I don't know."

Denyse O'Leary asks: Origin of life: How are we doing?. She is shocked to learn that scientists have not figured out all the details of how life began. She acts like she knows the answer. She acts like she has an explanation that accounts for all of the data and for the subsequent history of life.

Why isn't she sharing that information? How do the IDiots explain the origin of the first primitive cells more than 3 billion years ago?


Tuesday, October 22, 2013

Peter Hess of NCSE Tells Us About How to Make Evolution Compatible with Christianity

Minda Berbeco once taught evolution and she was surprised that her students wanted to talk about religion. She decided to consult with Peter Hess, the director of religious community outreach at the National Center for Science Education (NCSE). Her blog post is on the NCSE website at: When Students Ask about Religion.

Peter Hess mentioned that many people see a conflict between science and religion so Minda asked him what she should say to such people. Hess replied ...
I would recommend citing examples from the numerous scientists who have integrated current science into their religious worldviews, scientists such as Kenneth Miller, Francis Collins, Robert Russell, and Father George Coyne.

Another tack would be to cite statements from theological figures, such as Pope Benedict’s statement in Communion and Stewardship (2002), when he was still Cardinal Ratzinger:
Converging evidence from many studies in the physical and biological sciences furnishes mounting support for some theory of evolution to account for the development and diversification of life on earth, while controversy continues over the pace and mechanisms of evolution. While the story of human origins is complex and subject to revision, physical anthropology and molecular biology combine to make a convincing case for the origin of the human species in Africa about 150,000 years ago in a humanoid population of common genetic lineage.
Let me be clear: I’m not suggesting that you cite the views of such scientists and theologians as authoritative. There’s a wide range of religious reactions to evolution, from rejection to embrace, and you may not feel comfortable in endorsing any of them. (Indeed, a teacher in the public schools is required not to endorse any of them in the classroom.) But many people who reject evolution for religious reasons are ignorant about, or have never been seriously exposed to, the range of religious reactions to evolution. It may come as a complete surprise to them that devout religious people—perhaps even people of the same faith—have no theological objection to evolution. And opening people’s horizons is part of what education is all about, isn’t it?
There's so much wrong with this advice that I hardly know where to begin.

First, Hess seems to assume that Minda Berbeco is a Christian because otherwise his advice makes no sense. Surely, he wouldn't expect an atheist like me to tell students that the Pope is an authority on evolution? What if the teacher is a Muslim, a Buddhist, or a Hindu? What should they say? (Peter Hess is Roman Catholic.)

Second, he says that the views of these scientists (and the Pope) should not be cited as authoritative but if he really believes that then why cite them at all? Why not cite those religious scientists who think there really is a conflict between evolution and their religious beliefs?

Third, just because some scientists have been able to rationalize their acceptance of evolution with their Christian beliefs does not mean that there's no conflict. That is not a very good way to teach students how to think critically. After all, there are scientists who believe in homeopathy and astrology but that doesn't mean there's no conflict between real science and those pseudosciences, does it?

Fourthly, I agree that opening people's horizons is an important part of education. That's why I would tell students that, yes, there is a very real conflict between science and religion. It's quite likely that your faith will be severely challenged if you learn about evolution and science. Many students have never been seriously exposed to the atheist position. Somehow I don't think that's what Peter Hess has in mind when he talks about "opening people’s horizons."

Peter Hess recommends that students visit the Christian accommodationist webpages on the NCSE website [Science and Religion]. So, fifthly, I recommend that NCSE offer a more balanced view of this issue where they point out that there are many scientists who believe the conflict is very real. (I would be happy to write something.) NCSE should also expand their discussion to include non-Christian views of evolution.


The Trouble With Science

The purpose of a grant, after all, is to facilitate research. But the rationale has become curiously inverted: now the purpose of one’s research seems to be to get a grant ...

Jerry Coyne
This is a post for scientists and those who would be scientists.

Wake up!!! Science is in trouble! If you don't believe me, read How science goes wrong and Trouble at the lab. Both articles were published in the October 19th edition of The Economist.

It likely that you've heard all this before but the magnitude of the problem just hasn't registered with you. Well, it's time to start paying attention.

Jerry Coyne has written an excellent commentary on these articles [Science is in bad shape]. Read it. Now.

These articles and commentaries focus on research but let's not forget teaching. There are far too many science teachers—expecially at the university level—who are doing a terrible job of teaching evolution and biochemistry. (And probably lots of other subjects but those are the ones I'm familiar with.)

We have to do something about this.


Monday, October 21, 2013

Jukes to Crick on Junk DNA

Dan Graur discovered that the term "junk DNA" was commonly used in the 1960's—long before Susumu Ohno used "junk" in the title of his 1972 paper. This makes a lot of sense. Apparently the term was quite commonly used in Cambridge by people like Francis Crick and Sydney Brenner. (Perhaps you've heard of them?)

Graur found a 1963 paper that refers to "junk" DNA. This is the earliest known refencee to junk in the scientific literature. Read about his sleuthing at: The Origin of Junk DNA: A Historical Whodunnit.

Meanwhile, a person named "ShadiZl" commented on one my posts and pointed me to a letter from Thomas Jukes to Francis Crick in 1979. Jukes, you might recall, was no Darwinian. He was a proponent of Neutral Theory and random genetic drift. The letter is archived on the National Library of Medicine (USE) site under a section devoted to The Francis Crick Papers: Letter from Thomas H. Jukes to Francis Crick.

The letter is interesting because it reveals how casually the "insiders" talked about junk DNA and about the adaptationist misconception even as far back as 1979. This was when Gould and Lewontin published the "spandrels" paper. It also reveals how misguided the creationists are when it comes to the history of junk DNA. They still think that it was "Darwinists" who "predicted" junk DNA based on their view of natural selection. (Do not read this letter if you are irony-deficient. It will only confuse you.)
December 20, 1979

Dear Francis:

I am sure that you realize how frightfully angry a lot of people will be if you say that much of the DNA is junk. The geneticists will be angry because they think that DNA is sacred. The Darwinian evolutionists will be outraged because they believe every change in DNA that is accepted in evolution is necessarily an adaptive change. To suggest anything else is an insult to the sacred memory of Darwin.

This additive is so pervasive that if no reason can be found for an evolutionary change, it is necessary to invent one. Kimura points out that one author attributed the pink color of flamingos to protective coloration against the setting sun. This type of thinking carries over into people who sequence mRNA. They claim that differences between rabbit and human globin mRNAs are because each species has its own requirements for secondary structure.

Various people have tried to think up possible functions for the regions of DNA that do not code for anything as far as is known. Roy Britten says that such DNA has a regulatory function.

Actually, the scheme proposed by Britten about ten years ago was that occasionally events of saltatory duplication, took place, so that a great many copies of a short piece of DNA were made. As time went by, the composition of a family of identical copies became changed by drift, until the copies no longer closely resemble each other. Figure 55 of the article by Britten shows a diagram of a sort of "junk DNA generating system". I note that he says on page 105 "the rate of increase in DNA content per cell resulting from saltatory replication alone may prove to be embarrassingly large and a mechanism for the loss of DNA may have to be invoked". I gather that you agree with this.

I quoted you on drift in DNA in a talk that I gave at the symposium for Emil Smith (see enclosure). Your concept of "junk DNA" presumably includes this idea. I shall look forward to hearing more about it, and I have been asked by Die Naturwissenschaften to write an article on silent changes, so I hope I can include mention of your new manuscript when I start to write mine.

With best regards,


Thomas H. Jukes



Evolution Is Irrelevant to Michael Egnor

The title of this post suggest a story that's about as interesting as the proverbial "Dog Bites Man" story [see Man Bites Dog]. Nevertheless, from time to time it is amusing to see how the creationist mind works.

Michael Egnor is upset about the fact that the American Society for Biochemistry and Moleclar Biology (ASBMB) picked "evolution" as an important concept that should be covered in a biochemistry or molecular biology course. He doesn't like my post: ASBMB Core Concepts in Biochemistry and Molecular Biology: Evolution. He decided that he better convince his fellow creationists than biochemists don't know what they are talking about [Is Darwinian Evolution "Indispensable" to Biology?].

Here are some excerpts for your amusement.

Monday's Molecule #220

Last week's molecule was citrate synthase, one of many enzymes that show considerable amounts of structural change during binding. It looks like the "induced fit" mechanism is a general feature of substrate binding and not something that is limited to just a few examples. That part of the question was easy but the second part was hard. Jean-Marc Neuhaus is this week's winner because he has a copy of my book and was able to look up the explanation. The important point to keep in mind when you are thinking about the thermodynamics of biochemical reactions is that most reactions are near-equilibrium reactions where ΔG = 0. In the case of the citrate synthase reaction, ΔG°′ = -31.5 kJ mol-1, in the direction of citrate formation. What this means is that the equilibrium concentrations of the products are very much higher than the concentrations of the substrates. These concentrations would be closer to being equal if the reaction was coupled to substrate level phosphorylation (e.g. ATP formation). This would be a problem since the concentration of oxaloacetate (substrate) inside the cell is very low. (Because the standard free energy change of the malate dehydrogenase reaction is ΔG°′ = +30 kJ mol-1) [Monday's Molecule #219]. Jean-Marc lives in Switzerland so I've made arrangements to fly over there to visit him and treat him to fondue at the Pinte de Pierre-à-Bot in Neuchatel.

Today's molecule is one of those molecules that students should never be asked to memorize. It's an intermediate in a very important pathway. Identify the molecule and the pathway. You have to give me the full name and the common abbreviation. Email your answer to me at: Monday's Molecule #220. I'll hold off posting your answers for at least 24 hours. The first one with the correct answer wins. I will only post the names of people with mostly correct answers to avoid embarrassment. The winner will be treated to a free lunch.

There could be two winners. If the first correct answer isn't from an undergraduate student then I'll select a second winner from those undergraduates who post the correct answer. You will need to identify yourself as an undergraduate in order to win. (Put "undergraduate" at the bottom of your email message.)

Tuesday, October 15, 2013

ASBMB Core Concepts in Biochemistry and Molecular Biology: Evolution

Theme

Better Biochemistry
Tansey et al. (2013) have described the five core concepts in biochemistry and molecular biology. These are the fundamental concepts that all biochemistry instructors must teach and all biochemistry students must understand.

The five core concept categories are:
  1. evolution [ASBMB Core Concepts in Biochemistry and Molecular Biology: Evolution ]
  2. matter and energy transformation [ASBMB Core Concepts in Biochemistry and Molecular Biology: Matter and Energy Transformation]
  3. homeostasis [ASBMB Core Concepts in Biochemistry and Molecular Biology: Homeostasis]
  4. biological information [ASBMB Core Concepts in Biochemistry and Molecular Biology: Biological Information]
  5. macromolecular structure and function [ASBMB Core Concepts in Biochemistry and Molecular Biology: Molecular Structure and Function]

Darwinists Are Racists?

Intelligent Design Creationists are upset when I call them IDiots. They don't realize that the easiest way to make me stop is for them to stop acting like ... well, idiots.

The IDiots are fond of pointing out that they are all good Christians who would never stoop so low. They are all kind and gentle people who treat their opponents with respect and dignity. That's why they get so upset when we insult them.

Denyse O'Leary and the people who comment on Uncommon Descent have made these points repeatedly. They are the good guys and we are the bad guys when it comes to describing your opponents.

Let's look an example of how Christian IDiots behave. Denyse O'Leary recently wrote a post about The racist implications of Darwin’s theory.

She quotes a passage from Dawrin's The Descent of Man, and Selection in Relation to Sex.
The break between man and his nearest allies will then be wider, for it will intervene between man in a more civilised state, as we may hope, even than the Caucasian, and some ape as low as a baboon, instead of as now between the negro or Australian and the gorilla.
The quote is from page 201.

Denyse then says,
Darwin’s racism was not adopted out of bad will but simply as the logic of Darwinism. That is the point that every Darwinist wants to miss or downplay.

They have demanded that we all understand that the greatest man who ever lived wasn’t a racist and we are all misquoting or misunderstanding him or are bad, bad people or whatever for even bringing this stuff up.

Okay so we’re really awful here at Uncommon Descent. As our name implies, we don’t espouse any theory that says that humans are merely evolved animals or that we must inevitably form separate species as a result of isolation. Heck, we don’t even espouse a theory that says that separate species usually form that way. The evidence is mixed.

His believers are therefore stuck in the awkward position of having to pretend that what is obviously racist isn’t, and denouncing any of us who read the plain sense of it correctly.
Do you see the problem. Those poor IDiots are being criticized unjustly for seeing the obvious; namely, that all Darwinists are racists.

Doesn't your heart go out to them? Poor, poor IDiots.


Monday, October 14, 2013

Fundamental Concepts in Biochemistry and Molecular Biology

Theme

Better Biochemistry
The American Society for Biochemistry and Molecular Biology (ASBMB) advocates for a concept-driven approach to teaching biochemistry and molecular biology. It set up a number of working groups to flesh out this approach. The results have been published in a series of papers in the latest issue of BAMBED (Biochemistry and Molecular Biology Education). The first paper (Mattos et al. 2013) discussed the strategy [see ASBMB Promotes Concept Driven Teaching Strategies in Biochemistry and Molecular Biology].

The second paper, by Tansey, et al., is the most important paper. It covers the results of a two-year study to define and describe the fundamental concepts that must be taught. The authors begin by explaining why it's important to agree on a core set of fundamental concepts.

Monday's Molecule #219

Last week's molecule was cobalamin or vitamin B12. The structure was solved by Dorothy Crowfoot Hodgkin who won the Nobel Prize in Chemistry in 1964. There have been ten Nobel Prizes for work on vitamins and coenzymes. There were a lot of people who got this one right. The winner is Piotr Gasiorowski. The undergraduate winner is Jacob Toth [Monday's Molecule #218]. That makes four lunches that I owe Jacob. Right now, he's far away (British Columbia) but he may be coming to Toronto to collect. That may cut down on his chances of winning!

Today's molecule is a very common enzyme found in all species (I don't know of any exceptions). It's part of a pathway that's familiar to all biochemistry students. The figure illustrates a classic "induced fit" mechanism of substrate binding where the binding of one substrate creates the binding pocket for the second substrate. In this case, it's the homodimeric animal version of the enzyme showing rotation of the small domain of one of the subunits. Name the enzyme and the reaction it catalyzes.

There's more. In order to win a free lunch you have to explain something else. It's related to the fundamental concepts that all biochemistry students should know. The standard Gibbs free energy change for the reaction catalyzed by this enzyme is ΔG°′ = -31.5 kJ mol-1. What does that mean if you are trying to understand the reaction that takes place inside the cell? Is there a reason why this reaction isn't coupled to synthesis of ATP? I'm interested in seeing how most Sandwalk readers understand the fundamental concept of reaction thermodynamics.

Email your answers to me at: Monday's Molecule #219. I'll hold off posting your answers for at least 24 hours. The first one with the correct answer wins. I will only post the names of people with mostly correct answers to avoid embarrassment. The winner will be treated to a free lunch.

There could be two winners. If the first correct answer isn't from an undergraduate student then I'll select a second winner from those undergraduates who post the correct answer. You will need to identify yourself as an undergraduate in order to win. (Put "undergraduate" at the bottom of your email message.)

The Accommodationist View of Kevin Padian

In a recent post, I discussed the way Kevin Padian views evolution and why he thinks textbooks misrepresent evolution [see Misrepresentations of Evolution in Textbooks: Definition of Evolution According to Kevin Padian]. Now I want to quote his position on the conflict between science and religion.

Keep in mind that Kevin is President of the National Center for Science Education. He isn't speaking for NCSE in this paper but it's fair to say that his view is quite compatible with those of other members of the NCSE leadership.

Here's what Kevin writes under the subtitle "Avoid pitting science against religion, even though sometimes there are real conflicts" ...

Misrepresentations of Evolution in Textbooks: Definition of Evolution According to Kevin Padian

Kevin Padian is a professor at the University of California, Berkeley and Curator of Paleontology at the University of California Museum of Paleontology. He is also President of the National Center for Science Education (NCSE).

He wrote an article for Evolution: Education and Outreach in which he describes misrepresentations of evolution in textbooks (Padian, 2013). Since he is a prominent leader in the fight against creationism, we need to pay attention when he tells us how evolution should be taught in public schools.

Before examining some of those "misconceptions," let's review some earlier papers in Evolution: Education and Outreach. The very first issue contained an article by John N. Thompson where he defined evolution as ...
Evolution is quite simply heritable change in the genetic structure of a population. There is nothing in this or any similar standard definition of evolution that requires that genetic change in the average size, shape, or any other trait be maintained for a hundred, a thousand, or a million years before it can truly be called evolution. (Thompson, 2007)
Unfortunately, Thompson is under the mistaken impression that natural selection is the only significant mechanism of evolution but that's not the point. The point it that he, and many others, see evolution as a continuous and ongoing process that includes the minor fluctuations that Kevin Padian dismisses.

Friday, October 11, 2013

ASBMB Promotes Concept Driven Teaching Strategies in Biochemistry and Molecular Biology

The latest issue of BAMBED (Biochemistry and Molecular Biology Education) contains a series of articles on "Foundational Concepts and Assessment Tools for Biochemistry and Molecular Biology Educators." The goal is to get teachers to change their way of teaching undergraduate courses in biochemistry and molecular biology.

The first paper is an introduction to "Promoting Concept Driven Teaching Strategies in Biochemistry and Molecular Biology" (Mattos et al, 2013). The authors point out that ASBMB (American Society for Biochemistry and Molecular Biology) has been advocating concept driven teaching strategies for over a decade. What they don't mention is that this advocacy has been remarkably unsuccessful The majority of biochemistry and molecular biology courses are still taught in a memorize-regurgitate format. Most American courses are taught to the MCAT. Understanding concepts won't get you a good grade on the MCAT.

The idea of teaching fundamental concepts is useful if biochemistry and molecular biology are foundational courses designed as prerequisites for more advanced study. That's not how biochemistry is seen in most America colleges. Students usually don't take the course until their junior year and many don't take it until they are seniors! These courses are not generally seen as prerequisites for other courses in the biological sciences.

That's not how it works in Canada where biochemistry is a second year course and it is a prerequisite for many third year and fourth year courses. The importance of concept driven teaching should be more obvious in Canada. It isn't, in my experience. That doesn't mean we don't talk about it—or course we do. We all think that teaching concepts is a great idea. Problem is, we don't do it in our introductory courses.

This is one of the reasons why MOOCs are seen as a viable alternative to in-class biochemistry courses. You can spew out facts for multiple choice exams just as easily on a video as you do in a classroom. If, instead, we were actually teaching a concept driven course using a student-centered approach, then MOOCs would seem ridiculous.

Mattos et al. (2013) report that ASBMB developed a three pronged approach ...
  1. Building a network of scientists and educators focused on using and disseminating evidence-based teaching best practices.
  2. Fostering both an understanding of the use of appropriate assessment, and the creation of a network of educators focused on defining the foundational concepts of the discipline, identifying key cross-disciplinary principles, and incorporating the appropriate skills necessary for students to succeed in the practice of science into the curriculum and assessment of student outcomes.
  3. Promoting best practices in the education of our students by providing appropriate teaching and assessment resources for faculty.
They applied for, and received, a grant from the National Science Foundation (USA) to address these challenges. The results of those studies are ready to be published.

The next paper in this BAMBED issue describes the foundational concepts that all biochemistry & molecular biology instructors have to teach. Can you guess what they are before I post the answer? Put your best guesses in the comments.


Mattos, C., Johnson, M., White, H., Sears, D., Bailey, C. and Bell, E. (2013) Introduction: Promoting concept driven teaching strategies in biochemistry and molecular biology. Biochem. Mol. Biol. Educ. 41:287–288. [doi: 10.1002/bmb.20726]