Simple Ain’t So Simple Anymore

Biology Concepts – prokaryotes, simplicity, complexity, organelles, microcompartments

Not everything new is better; new doesn’t

necessarily mean improved. Remember the
“New” Coke debacle?

Newer is better, right? Everything old is simple and plain. Back in the good old days, you had to read a book, but today you can browse the internet and pick from 8000 songs while you drive to the superstore to pick up a Kindle. Today is faster. Better. More complex?

How about living in 1800. Could you catch and kill your dinner with a trap of your own making, followed by gutting and dressing it on the back porch of a house you built with your own hands, while you try to keep your entire family from being eaten or dying from an infected scratch?  Now whose world seems complex!

This same belief has been applied to forms of life. Bacteria are old and simple; we are new and complex. Plants and animals can do millions of things that bacteria can’t, because they are so simple and primitive and we are so high tech, biologically speaking.

But it is a mistake to call bacteria simple or primitive. They may not have all the bells and whistles that eukaryotic (eu - true and karyo = nucleus) cells have, but they have survived much longer than other life forms, and they outnumber us by billions. There are more bacteria in a handful of rich soil than people who have ever lived on Earth. So don’t confuse complexity with success.

A cursory look at bacteria would suggest that they are indeed simple. They are bags of chemicals, without the complex organelles that mark eukaryotic cells. Plus, they're small; the whole organism is just one cell. They have just one chromosome and fewer genes than eukaryotic cells. It would be easy to see them as simple.

Even at the biochemical level prokaryotes (pro = primitive) appear simple compared to eukaryotic cells. Our more modern cells aren’t satisfied with just making more proteins, they also modify many of these proteins, adding carbohydrates, acetyl groups, phosphate groups, sulfur groups, etc. These post-translational modifications (after peptides are translated from mRNA messages) are crucial for different functions and for interactions with messengers and DNA.

Histones are protein complexes that help DNA to coil up into tight 
configurations. But DNA it is tightly packaged, it is hard for 
individual genes to be transcribed and made into protein. Histone 
acetyltransferases are enzymes that add acetyl groups to the histones 
and open DNA to be read. Histone deacteylases do the 
opposite, they add acetyl groups and cause the DNA 
to tightly coil.

The exception here is that less than a decade ago scientists found that many prokaryotes also do some kinds of post-translational modifications, includingphosphorylation and acetylation. Acetylation, the addition of a -COCH₃ group to a molecule, is important in eukaryotic cells for several reasons, not the least of which is in determining which DNA is open to be replicated or transcribed (copied to mRNA).

Data from 2004 was the first to show that prokaryotes can carry out phosphorylation (addition of PO₃ groups) to proteins. What is more, acetylation and phosphorylation are reversible modifications, so an additional layer of complexity is added. Prokaryotic proteins have one function when modified and another when not modified, just like modification of eukaryotic proteins. Sounds like prokaryotes have more going on than we thought.

Prokaryotes are the real success stories of life on Earth. They can do things some things eukaryotes can’t do (more on this next time). Even more amazing, every deficit we have said they have - they can’t do this, they don’t have those – can be seen as a reason they are more amazing.

Prokaryotes are single celled organisms, so they have less specialization. But this means that the cell has to carry out every function that the organism needs. Could your fat cells produce antibodies and kill off protozoan invaders? I think not. We also poke fun at prokaryotes because they don’t have organelles; but this means they have to find a way to do all their chemistry in one big open environment, much more difficult .……….or maybe not.

That classic rule of biology, "eukaryotic cells have organelles and prokaryotic cells don’t," may not be completely true. This would be a big exception.  Evidence shows that many kinds of prokaryotes do have local environments, called microcompartments. We have all been living a lie!

The most studied of the microcompartments is the carboxysome. This hollow shell, first described as far back as 1956, holds enzymes (RuBisCo, see When Amazing Isn’t Enough) that many prokaryotes use for carbon fixation. Photosynthesis is the most obvious type of carbon fixation, where carbon in a gas form (CO₂) is converted to carbon in an organic, solid form (carbohydrates).

Carboxysomes as seen by electron microscopy. They really

do look geometric. The faces and corners are specific groups

of proteins, and hold the enzymes inside the microcompartment.

There are minute pores where the proteins come together

to let reagents and products move in and out of the carboxysome.

RuBisCo is a fairly inefficient enzyme, so sequestering it with its substrate inside a microcompartment works to increase the production of energy. Doesn’t this sound a lot like one of the key reasons for the development of organelles – the bringing together of reagents for increased efficiency of reactions?

But it is not just photosynthetic bacteria (cyanobacteria) that use carboxysomes. Many other autotrophic bacteria (auto = own and troph = food) use carboxysomes to fix carbon during chemosynthesis. Chemoautotrophs, for instance, are organisms that use chemical energy rather than sunlight energy to fix carbon.

In many prokaryotes, the oxidation of hydrogen sulfide or ammonia (a nitrogen containing compound) provides the energy for producing organic carbon; Thiomargarita namibinesis from our posts on giant bacteria uses sulfur for chemosynthesis. But there are also organisms that use the energy from the production of methane to drive carbon fixation. You have undoubtedly had experience with intestinal prokaryotes that produce methane gas (methanogens) – don’t try to say you haven’t.

The carboxysome (as a model of many microcompartments) is not a membrane bound bag as organelles are in eukaryotes. Carboxysomes are more like soccer balls made of protein, but in this case they hold a rigid polyhedral form and don’t get bicycle kicked into a prokaryotic net by Pele.

Each face of the shell is made up of a two dimensional polymer of protein hexagons. However, as architects will tell you, this is a difficult shape to close using only hexagons, even with 10,000 of them, like the typical carboxysome has. Soccer balls and the dome at the Epcot Center use strategically placed pentagonal faces that allow for the turning of the hexagonal faces and a closing of the compartment (see cartoon above).

These are cartoons showing the structure of a

carbon fullerene (right) and a carbon nanotube

(left). Each green sphere represents a carbon atom.

These structures are very strong, like for making

bicycle helmets. They may also become useful for

things like space elevators, nanoelectrical circuits,

and solid lubricants.

We have used this hexagonal and pentagonal combination for decades, but it was identified in bacteria less than five years ago. This arrangement is also seen in viral protein coats, as well as in carbon fullerenes, which are superstable carbon nanostructures described in 1985 and named for the inventor of the geodesic dome, Buckminster Fuller.

Could this be the exception – nature stealing an idea from humans? Probably not, I’m guessing Dr. Fuller independently happened upon the same solution that nature had worked out millions of years ago – but it took a heck of an intellect to recognize a good thing.

It might be lucky for us that Fuller’s domes had us looking for this combination in other areas. Carboxysomes are present in up to 25% prokaryotic pathogens (disease causing organisms), and current research is aiming to disrupt the formation of the hexagonal/pentagonal compartments as a way to kill, or at least slow down, the microbes. So many prokaryotic pathogens are developing resistance to traditional antibiotics that a new approach will be heartily welcomed.

There are other microcompartments besides the carboxysome. The bacterium Clostridium kluyveri is proposed to have a metabolosome compartment for the conversion of ethanol into carbohydrates. Furthermore, Salmonella enterica, is capable of producing two different metabolosomes; one for propane-1,2-diol and one for ethanolamine, for conversion of these substrates into energy-containing carbon sources.

The evidence of these additional microcompartments makes one wonder just how many different species of protein shelled microcompartments there may be. To investigate this question, a group from UCLA recently published a study using comparative genomics (comparing genes of similar and dissimilar organisms to find groups of genes of similar function) to point out possible enzyme pathways that may be sequestered in microcompartments.

Their late 2012 study suggests that new types of microcompartments for different types of propanediol metabolism, and the identification of microcompartments in organisms for which they were previously unknown, like mycobacteria. The genomic evidence also suggests new types of protein shells, differing compartments being used for differing variants of enzyme function.

It is in these final examples that we see a more concrete purpose for the microcompartment. During the metabolism of alcohol, propane-1,2-diol, or ethanolamine, a compound called acetaldehyde is formed. This is a toxic product that needs to be converted to acetic acid in rapid order to avoid toxicity to the cell. By isolating the acetaldehyde in the metabolosome, S. enterica improves its own living conditions. This is also important to us humans.

This is not a before and after picture for an embarrassing

karaoke incident. This is a demonstration of the facial

flushing reaction when a person has an ALDH2 mutation, and 
can’t metabolize alcohol efficiently.

Many Asians and Ashkenazi Jews have a mutation of the acetaldehyde dehydrogenase (ALDH₂) gene that produces the enzyme that rids the body of acetaldehyde after the consumption of alcohol. The mutation produces a poorly functioning enzyme, so acetaldehyde builds up in their systems and causes a facial flushing reaction. If both ALDH₂ genes (one from mom, one from dad) are mutated, the person gets violently ill from consuming ethanol. As you might imagine, populations in which this mutation is prevalent have very low rates of alcoholism.

So we have the exception that prokaryotes are not really without organelles; theirs just look different. Could you guess that the exception goes the other way too? Well, it does. The nucleus of eukaryotic cells works with microcompartments that allow certain things in and out, but keep your DNA inside the nucleus.

The pores of the nucleus (Cells Are Great Multitaskers) are complex openings made up of many proteins. Why? Nuclei could just use receptors to allows certain things in or out, similar to the system used by the cell plasma membrane. But evolution went with a more complex solution.

The vault complex is made of 78 identical protein chains.

One chain is shown in white. Together, they form a

microcompartment that is crucial for our nucleus function.

There is a protein microcompartment called a vault complex that works with the pore complex. This is a highly regulated way of moving RNAs and ribosomes (made in the nucleolus which is inside the nucleus) out of the nucleus, while keeping your DNA inside. I don’t think it is a hard concept to grasp that you cells are happier when your DNA stays inside the nucleus; do you keep your valuables on your front lawn?

Next time we will see how the nucleus, its pore complex, and its microcompartment carriers helped us make the jump from prokaryote to eukaryote. The nucleus is a later evolutionary development, but it still uses a prokaryotic system. This is clue that helps us investigate our cellular family tree. 

Jorda, J., Lopez, D., Wheatley, N., & Yeates, T. (2012). Using comparative genomics to uncover new kinds of protein-based metabolic organelles in bacteria Protein Science DOI: 10.1002/pro.2196




For more information or classroom activities on bacterial microcomponents, post-translational modification of proteins, alcohol metabolism, or the vault complex, see:

Bacterial microcomponents –

http://www.sciencedaily.com/releases/2008/02/080221152009.htm

http://schaechter.asmblog.org/schaechter/2011/04/beyond-the-bacterial-microcompartment.html?utm_source=feedburner&utm_medium=feed&utm_campaign=Feed%3A+schaechter+%28Small+Things+Considered%29

http://www.microbemagazine.org/index.php/06-2010-home/1863-the-carboxysome-and-other-bacterial-microcompartments

www.asm.org/ccLibraryFiles/Filename/.../znw00107000025.pdf

http://www1.cnsi.ucla.edu/arr/paper?paper_id=196039

http://scienceblogs.com/oscillator/2010/03/bacterial_organelles.php

http://www.microbialcellfactories.com/content/10/1/92

Protein post-translational modification –

http://www.piercenet.com/browse.cfm?fldID=7CE3FCF5-0DA0-4378-A513-2E35E5E3B49B

http://themedicalbiochemistrypage.org/protein-modifications.php

http://www.premierbiosoft.com/glycan/glossary/post-translational-modifications.html

http://www.cook.rutgers.edu/~dbm/posttrans.html

http://www.juliantrubin.com/encyclopedia/bioinformatics/proteomics.html

Alcohol metabolism –

http://www.elmhurst.edu/~chm/vchembook/642alcoholmet.html

http://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=9&ved=0CGMQFjAI&url=http%3A%2F%2Fjournals.cambridge.org%2Fproduction%2Faction%2FcjoGetFulltext%3Ffulltextid%3D980664&ei=v4lvT-KgBci-gAfuwonpBw&usg=AFQjCNEf-W1CVy-a75h8Z1s1HVLbtVhkSA

http://science.howstuffworks.com/environmental/life/human-biology/hangover4.htm

http://hamsnetwork.org/metabolism/

http://en.wikipedia.org/wiki/Alcohol_flush_reaction

http://ethemes.missouri.edu/themes/315

Nuclear vault complex –

http://www.vaults.arc.ucla.edu/pages/sci-pores

http://micro.magnet.fsu.edu/cells/nucleus/nuclearpores.html

http://www.ks.uiuc.edu/Research/npc/

http://en.wikipedia.org/wiki/Vault_%28organelle%29

Cells Are Great Multitaskers

Biology concepts – compartmentalization, organelle function, cellular biochemistry

This chart represents a portion of the cellular reactions

that are taking place every second in a mammalian cell.

It looks more like a multicolored plate of pasta, but

shows you how complex a single cell is, and remember

that this doesn’t even count all the reactions for one cell

to be able to talk to another cell.

It is hard to estimate the number of reactions that must take place in a cell every second in order to keep a cell alive and performing its jobs(s)...... but I bet it is more than seven or eight.

The typical mammalian cell contains 2000 or more different proteins as well as many thousands of non-proteins (lipids, carbohydrates, and nucleic acids). Each molecule is crucial for carrying out chemical reactions, and each individual molecule is itself produced, modified, and destroyed by chemical reactions.

When I started to think about all this chemical activity, I looked to see if someone had counted, or at least estimated, the number of reactions taking place in the cell at any one time. I got no answer, not even a reliable guess from a credible source.

Think of it in this light, a plant cell has to perform more than twenty reactions to convert one photon of light into the chemical energy that will later be used for the synthesis of glucose. Each of these twenty reactions is occurring simultaneously at least hundreds of times in every chloroplast of the plant cell, and a single plant cell might have more than one hundred chloroplasts. The numbers add up fast, but remember that production of carbohydrate from light energy is just one of thousands of functions of a plant cell. There are chemical reactions occurring every second for all of these functions.

All this chemistry results in perhaps hundreds of thousands or millions of reactions each second, and all taking place within the confines of a cell that is too small to be seen with the naked eye. Wow!

When talking to students, I often use the analogy that a cell is like a factory, producing many different products at the same time. Not unlike a factory, a cell has to perform many functions, such as energy production, product manufacture, oversight and management, transportation of products, quality checks, and cleanup. What complicates matters is that all these different jobs have to be able to occur simultaneously.

I often use the analogy that a cell is like a factory, with

different departments. Other like the cell as a city

analogy. I even had one student make the analogy

that the cell is like a movie set, where the nucleus is

the director, and the plasma membrane is the fence

around the movie lot, etc.   She got an A.

How can a factory, or a cell for that matter, keep all the parts for all the different products, all the different workers, and all the different processes and jobs from messing each other up? A factory does this by setting up departments, where individual jobs take place, and then creating management teams that coordinate the work of the different departments—although to often there is too much management and too little production, but that is another matter.

The business and manufacturing industries stole this strategy from the cell, just as most our good ideas have been copied from nature. The cell uses compartments to increase the efficiency of all its needed chemical reactions. In eukaryotic (eu = true, and karyo= nucleus) cells, the compartments are called organelles (organ = instrument and elle = small), most of which are membrane bound containers.

Remember in our discussion of why cells must be small (It’s All In The Numbers) we said that mixing rate (time needed for a molecule to become evenly dispersed in a cell) and traffic time (time needed for two molecules needed for a certain reaction to find one another) are important for determining the maximum size of a cell.

Membrane bound organelles sequester needed components and create different local environments so that their mixing rates and traffic times are reduced. The result is a cell that is more efficient and can be bigger. This is evidenced by the fact that prokaryotic (pro = before) cells, such as bacteria, don’t have organelles and are about 50 times smaller than eukaryotic cells which have evolved organelles.

The nucleus has two membranes that form an envelope.

The outer membrane is continued as the endoplasmic

reticulum (ER), another vital cell organelle. The ribosome

attached to the ER, so it is easy to see how the organelles

work together to make a functioning cell.

The membranes of organelles look a lot like the membrane that surrounds the cell itself, but organelle membranes are often modified for their particular job. Take the nucleus (Welsh for "kernel of a nut," meaning the central part of a thing) for instance. It has two membranes and nuclear pores that run through both membranes are very specific for what they will let into and out of the nucleus.

The plasma membrane of the cell also limits the passage of molecules, but the nuclear pores are a complex of many unique proteins and this structure that is nowhere to be seen on the cell’s plasma membrane. Just like the membrane of the cell separates what is in the cell from what is outside the cell, the membrane of the organelle separates the needed components of their reactions from all the unneeded components of the cell.

In addition, many chemical reactions in organelles require the membrane as a workbench. Thousands of reactions take place in or across the membrane. This is an important function of many types of organelles, they increase the membrane surface area of a cell without making it bigger.

Some cellular reactions produce or use an intermediate molecule that must be separated across a membrane in order for the rest of the reaction to take place. This is the case for the mitochondrion – the energy producer in eukaryotic cells. To produce ATP (adenosine triphosphate, the chemical currency unit of energy in the cell), the mitochondrion sets up a gradient of protons between two membranes (remember that the nucleus has two membranes also) of the mitochondrion. The energy from the leaking of protons back into the inner space is used to produce ATP. We will talk more about these organelles with two membranes in an upcoming post.

Second messenger systems allow for messages from outside

the cell to be transmitted throughout the cell. There are three

general types, including one for gases like nitric oxide. In all,

there are more than two dozen different signal transduction

cascades, each with its own set of reactions.

Likewise, the outer membrane of the cell has many jobs that require messages to be transferred from one side of the membrane to the other. Called second messenger systems, these reactions are mechanisms to bring messages from outside the cell to the inside of the cell without the need for anything to cross the cell’s boundary.

In some cases, the membrane is not enough compartmentalization. The lysosome is an interesting organelle whose job is to break down many complexes that are brought into a cell and to recycle old organelles so the cell can reuse the parts. To do this, the lysosome contains proteins that can eat up other proteins, lipids, and carbohydrates. Unfortunately, these are the exact same molecules that make up the cell and the lysosomal membrane themselves. So why doesn’t the lysosome digest itself, and the entire cell for that matter?

The protein enzymes in the lysosome work efficiently within a narrow range of acid pH. Therefore, this organelle is acidified when produced. If the lysosome ruptures, the 7.2 pH of the cytoplasm will inactivate the lysosomal acid hydrolases, so the cell is protected. In addition, the lysosome membrane has many sugars stuck to it that act as a buffer between the lipids and proteins of the lysosomal membrane and lysosomal enzymes. There probably is some damage to the lysosome membrane, but repair reactions also help to keep the membrane intact. The cell often has redundant systems for safety.

So, we have seen that many of the organelles function to keep things sequestered in the cell, either for protection, organization, efficiency, or function. However, there are other reasons why organelles are a good idea.

Osteoclasts and osteoblasts are hard workers, so much so

that they needed more than one set of instructions for their

work. The osteoclast above shows multiple nuclei for many

DNA copies. Sometimes separate osteoblasts will join

together to form a multinucleated giant cell.

Organelles increase specificity, both for individual reactions and for cellular activity as a whole. Many cells in multicellular organisms are specialized for a certain function, and their organelles help them carry out this function. For instance, muscle cells are specialized for contraction, and this requires lots of energy. Therefore, they need many mitochondria, but few other types of organelles. These cells might contain 10-100 times more mitochondria than other cell types.

Likewise, osteoclasts (osteo = bone, clast = break) cells break down bone – and yes, you are breaking down and rebuilding your bones every second of every day. This activity requires many proteins to be produced, and one set of DNA instruction housed in one nucleus is often insufficient for the job. Therefore, these cells often have two or more nuclei in order to get the job done.  In these ways, specialization of organelle compartments and combinations allows for specialization of cellular function.

Centrioles are organelles important for the cellular

division. They are also a target for cancer therapy,

since many cancer cells have more than the regular

set of two centrioles.

As we have seen in every topic we have investigated, there are exceptions in the world of organelles. Some organelles are not membrane bound bags that carry things around or house certain reactions. Ribosomes are cellular organelles that make proteins, but they have no membrane. The cytoskeleton elements help the cell hold its structure, help the cell move, and help move other organelles move around within the cell, but they are not membrane bound either. Other cellular components, like the mitotic spindles of the centrioles that pull chromosomes apart when the cell undergoes mitosis are proteins that are present at only certain times in the animal cell. Even more confusing, plant cells divide similar to animal cells, but don’t have centriole organelles.

The take home message is that these organelles, whether membrane bound or not, perform vital services for the cell and make the many cellular reactions possible. The general modus operandi for organelles is that they carry out their functions with in the cell, but one type of organelle is the exception, it’s the traveling organelle.

Song RL, Liu XZ, Zhu JQ, Zhang JM, Gao Q, Zhao HY, Sheng AZ, Yuan Y, Gu JH, Zou H, Wang QC, & Liu ZP (2014). New roles of filopodia and podosomes in the differentiation and fusion process of osteoclasts. Genetics and molecular research : GMR, 13 (3), 4776-87 PMID: 25062413

Saltman LH, Javed A, Ribadeneyra J, Hussain S, Young DW, Osdoby P, Amcheslavsky A, van Wijnen AJ, Stein JL, Stein GS, Lian JB, & Bar-Shavit Z (2005). Organization of transcriptional regulatory machinery in osteoclast nuclei: compartmentalization of Runx1. Journal of cellular physiology, 204 (3), 871-80 PMID: 15828028


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For more information on organelles, see:

Organelles –

http://biology.clc.uc.edu/courses/bio104/cells.htm

http://people.usd.edu/~bgoodman/ReviewFrames.htm

http://library.thinkquest.org/trio/TR0110561/organelles.htm

http://www.cellsalive.com/cells/cell_model.htm

http://utahscience.oremjr.alpine.k12.ut.us/sciber00/7th/cells/sciber/orgtable.htm

http://www.sumanasinc.com/webcontent/animations/content/organelles.html

http://www.youtube.com/watch?v=LP7xAr2FDFU

http://www.biology4kids.com/files/cell_main.html

http://www.vetmed.vt.edu/education/curriculum/vm8054/labs/lab3/lab3.htm

http://www.nobelprize.org/educational/medicine/cell/

http://waynesword.palomar.edu/lmexer1a.htm

http://www.lessonplansinc.com/biology_lesson_plans_cell_organelles.php

http://alex.state.al.us/lesson_view.php?id=23925

http://teachingtoday.glencoe.com/lessonplans/the-cell

http://www.galaxygoo.org/biochem/CellProject/the_cell.html

http://www.etap.org/demo/grade7_science/instruction2tutor.html

http://blog.sciencegeekgirl.com/2010/01/12/hands-on-class-activities-on-the-cell/

http://www.ehow.co.uk/info_8237178_student-activities-cell-organelles.html

http://www.schools.manatee.k12.fl.us/072JOCONNOR/celllessonplans/lesson_plan__cell_structure_and_function.html

http://sciencenetlinks.com/lessons/cells-2-the-cell-as-a-system/

http://classroom.jc-schools.net/sci-units/cells.htm

http://www.teach-nology.com/teachers/lesson_plans/science/biology/cell/