Cornering multiple sclerosis -- still a long way to go

Multiple sclerosis is an autoimmune disease of the central nervous system that causes neurological disability in young adults. Several environmental and genetic factors have been linked to the disease, but the precise mechanisms involved, and whether neurological damage precedes inflammation or vice versa, remain unclear.

In a recent article published in Nature, an international consortium of researchers report the identification of 29 new susceptibility loci, most of which are related to immune system function and, in particular, to T-helper-cell differentiation.

Previous genome-wide association studies (GWAS) that analysed relatively modest numbers of multiple sclerosis patients identified more than 20 risk loci, especially some that encode components of the major histocompatibility complex (MHC). To identify a more complete set of susceptibility loci and obtain new insights into disease mechanisms, an international team of researchers carried out a large GWAS in which they analyzed over 465,000 autosomal single nucleotide polymorphisms (SNPs) from about 9,800 patients and 17,400 controls (that is, people not affected by multiple sclerosis) from 15 countries.

This analysis confirmed 23 loci that had previously been linked to the disease, and revealed another 29 new loci. Most of the risk attributable to the MHC could be accounted by four mutations, one in class-I locus HLA-A and three in class-II locus HLA-DRB1.

A statistical analysis of the functions of the 52 loci (as annotated in the Gene Ontology database) showed that they are enriched for lymphocyte functions. In particular, many genes encoding cell surface receptors (such as CXCR5 and IL7R) with roles in T-helper-cell differentiation showed strong association with multiple sclerosis. In addition, the researchers identified two susceptibility loci with a role in vitamin D synthesis (CYP27B1 and CYP24A1) and others that encode known targets of therapies for multiple sclerosis such as natalizumab (VCAM1) and daclizumab (IL2RA). By contrast, very few genes with known roles in inflammation-independent neurodegeneration were identified.

The overrepresentation of susceptibility genes with roles in T-cell maturation suggests that multiple sclerosis is primarily caused by immune dysfunction, which is followed by neurological damage. However, the 52 variants can explain only ~20% of the heritability of the disease, and therefore a myriad of other susceptibility loci, each adding a tiny percentage to the overall risk of developing multiple sclerosis, remain to be identified.


Original article:
The International Multiple Sclerosis Genetics Consortium & The Wellcome Trust Case Control Consortium 2 (2011). Genetic risk and a primary role for cell-mediated immune mechanisms in multiple sclerosis Nature, 476 (7359), 214-219 DOI: 10.1038/nature10251


The same story in the news:
- Study identifies 57 genes linked with MS, Multiple Sclerosis Society, UK (10 Aug 2011).
- Multiple sclerosis genes identified in largest-ever study of the disease by Alok Jha, The Guardian (10 Aug 2011).
- Scientists unravel genetic clues to multiple sclerosis by Kate Kelland, Reuters (10 Aug 2011).


Note:
During the last 10 months, I have written 18 Research Highlights (short pieces of 300-400 words that summarize recent scientific articles) for Nature Reviews Microbiology. This blog post is based on my first attempt to write a similar piece about a non-microbiological article. However, to make the post more 'blog-friendly', I have embedded some links to definitions of key terms. You can read the definitions by rolling your mouse over the highlighted terms, or you can click on the term to visit a website with more information. Also, I have added a couple of links to news articles that covered the same story.

Read the rest of the article >>>

A cell potpourri: eukaryotes and their organelles

According to the endosymbiotic theory, eukaryotic organelles (mitochondria, chloroplasts) are the remains of certain bacteria that established intimate associations with eukaryote ancestors. This theory is widely supported by biochemical, genetic and proteomic evidences. A take-home message may be: a bacterium became an endosymbiont, then degenerated, and voilà, turned into an organelle. But that's an oversimplification. A full story should include an active participation of the host, some horizontal gene transfer from different microbial sources and, most likely, the involvement of other endosymbiotic partners that became extinct long time ago.

The origin of mitochondria, through the association between a eukaryotic ancestor and an alpha-proteobacterium (perhaps similar to Rickettsia) was a crucial, early event: thusfar, all eukaryotes examined possess mitochondria or mitochondria-related compartments, or at least some genes derived from such an organelle. About 1.5 billion years ago, a cyanobacterium joined the partnership to give rise to plastids in a common ancestor of red and green algae, land plants and glaucophytes (together the Archaeplastida). Although the identity of the cyanobacterial symbiont is far from clear, recent studies support the hypothesis that it might be similar to contemporary Nostoc or Anabaena. Many of these filamentous, nitrogen-fixing cyanobacteria are endosymbionts, which generally provide nitrogen to their hosts (this agrees with suggestions that nitrogen fixed by the endosymbiont might have played an important role during the origin of plastids). These organelles were later spread through secondary endosymbioses, that is, plastid-containing eukaryotes were engulfed by other eukaryotes; this process has occurred several times and has produced an astonishing diversity of photosynthetic organisms.

For a bacterium to become a permanent endosymbiont and, eventually, an organelle, some new functions had to be developed, or re-adapted from old ones. Firstly, a controlled exchange of metabolites ("food", waste products, ions) had to be established between the host cell and the endosymbiont. Additionally, the two partners had somehow to coordinate cell division, to assure that at least one endosymbiont cell was included in each daughter cell when the host reproduced.


Gene loss and gene transfer to the nucleus

On the other side, long-term endosymbionts could get rid of many functions that were required by free-living bacteria, and many unnecessary genes were lost. In general, genomes of mitochondria and plastids are about 10-20 times smaller than genomes of present-day Rickettsia and free-living cyanobacteria, respectively. Actually, the number of protein-coding genes in organellar genomes is very small (3-70 for mitochondria, 50-200 for chloroplasts). Does this mean that only 3 (or 50) proteins are needed for a mitochondrion (or chloroplast) to function? Of course not — these organelles are complicated molecular machines, requiring the coordinated action of several hundreds or thousands of different proteins. However, most of these proteins are not coded in the organelle genome but in the nuclear DNA. That is, many bacterial genes were lost, and most of the remaining genes were transferred to the host genome. Apparently, the nucleus is a safer environment for DNA: deleterious mutations may accumulate at a faster pace in organelles, due to a higher mutation rate caused by oxygen free-radicals, in addition to the non-recombining nature and small population size of organelle genomes. Then, it is not clear why mitochondria and chloroplasts retain a genome at all. Perhaps each type of organelle needs to keep a minimum set of key genes that are subject to a fast and tight regulation depending on local (organelle) conditions; or the encoded proteins cannot be efficiently transported into the organelle. On the other hand, some organelles do exist that appear to lack a genome — the hydrogenosomes, which might be derived from mitochondria.

Once the endosymbiont genes landed on the nuclear genome, they had to suffer some modifications to be properly expressed in the new location. Additionally, nuclear genes are, by default, translated into proteins in the host cytoplasm — if these proteins need to function in the endosymbiont cell, they have to be properly targeted and directed to the right compartment. This required the development, or re-adaptation, of an efficient system for protein targeting and translocation.


With a little help from some friends

Interestingly, both cellular partners were active players in organelle establishment: all key functions required for endosymbiosis were driven by combinations of endosymbiont- and host-derived proteins. Organelle proteomes are a potpourri of proteins with diverse origins: a surprisingly large pool was derived from the host, while other proteins were provided by multiple symbionts and/or horizontal gene transfer. A study of the yeast mitochondrial proteome showed a predominant eukaryotic origin (about 50%), and only about 15% of the proteins came from alpha-proteobacteria; the remainder had other prokaryotic origin. In the case of the plastid proteome, most proteins (1,000-1,500) are derived from cyanobacteria, and several hundreds are of eukaryotic origin.


Chlamydiae and the origin of plastids

Recent sudies have shed new light on the origin of plastids, suggesting the involvement of another group of bacteria, the chlamydiae. Present-day chlamydiae live as obligate intracellular parasites in eukaryotic cells. Many chlamydiae are pathogens of humans and animals, while others are found as endosymbionts in amoebae and insects; thusfar, they have not been found in plants or other plastid-containing eukaryotes. Nevertheless, it was known for some time that an unexpected number of chlamydial genes were most similar to plant homologs, most of which contained a plastid-targeting signal. This observation prompted several hypotheses, including an ancestral evolutionary relationship between chlamydiae and the cyanobacterial donor of the plastid, and horizontal gene transfer between the two groups. It was also suggested that plants might have acquired these genes through intermediate vectors such as infected insects.

A phylogenomic analysis of 17 Archaeplastida species has shown that at least 55 genes were transferred between chlamydiae and primary photosynthetic eukaryotes. Two thirds of the genes appear to encode plastid proteins, while the rest may have other cellular functions (including mitochondrial functions). The data provided strong evidence for a long-term symbiotic association between chlamydia-like cells and the Archaeplastida ancestor. It is possible that both cyanobacterial and chlamydial endosymbionts may have co-existed in the cell. It is not clear if the chlamydial association consisted of a recurrent infection by one or more specific endoparasites (as occurs in contemporary chlamydiae and their eukaryotic hosts), or an organelle-like endosymbiosis. While the cyanobacterium provided the photosynthetic function and was retained as an organelle, the chlamydiae supplied a number of key genes, including those coding for some metabolite transporters used by the plastid (especially the ADP/ATP translocator). This facilitated the communications between the cyanobacterium and the eukaryotic cell. However, the chlamydial partner was eventually eliminated by the host, once it became an unnecessary burden.


Endosymbionts or organelles?

The establishment of plastids from cyanobacteria probably occurred only once in a common ancestor of Archaeplastida; this was thought to be the only example of primary endosymbiosis leading to a photosynthetic eukaryote. However, another independent case of primary endosymbiosis is now known: Paulinella chromatophora is an autotrophic amoeba that contains two photosynthetic bodies that appear to have been acquired much more recently than the plastids of all other eukaryotes by the uptake of a Synechococcus-like cyanobacterium. Other examples of extreme bacterial endosymbionts, or pseudo-organelles, include Buchnera (in aphid insects) and Carsonella (with a tiny 160-kilobase genome, in psyllid insects). Additionally, the transfer of a complete genome from an endosymbiont to the host chromosome has been well documented for Wolbachia (in several insects).

Nature is unfinished...



Scholar articles (open access):

• Huang, J., Gogarten, J. (2007). Did an ancient chlamydial endosymbiosis facilitate the establishment of primary plastids? Genome Biology, 8(6), R99. DOI: 10.1186/gb-2007-8-6-r99
• Moustafa, A., Reyes-Prieto, A., Bhattacharya, D., DeSalle, R. (2008). Chlamydiae has contributed at least 55 genes to Plantae with predominantly plastid functions. PLoS ONE, 3(5), e2205. DOI: 10.1371/journal.pone.0002205

Related links:

• The evolution of organelles. An animated tutorial produced by Sumanas, Inc.
• It takes teamwork: how endosymbiosis changed life on Earth. Understanding Evolution.
• Endosymbiosis and the origin of eukaryotes. Kimball's Biology Pages.
• Endosymbiotic theory. Wikipedia.
• Play It Again, Cyan (on Paulinella chromatophora). Small Things Considered (April 20, 2008).
• Talmudic Question #24: Why didn't mitochondria and chloroplasts cede all of their DNA to the nucleus, as did most hydrogenosomes and certain other organelles? Small Things Considered (Nov. 19, 2007).
• From Free-Living Bacterium to Cellular Citizen, Small Things Considered (Sept. 3, 2007).
• Caught in the Act (on a case of secondary endosymbiosis), Small Things Considered (May 2, 2007).

Image credits:

• Unnamed artwork of a plant cell: Photo by R.W.W. (Ambra Galassi) on Flickr.
• Chlamydiae and the origin of plastids: Figure 4 from Moustafa A, Reyes-Prieto A, Bhattacharya D (2008) Chlamydiae Has Contributed at Least 55 Genes to Plantae with Predominantly Plastid Functions. PLoS ONE 3(5): e2205.
  

Read the rest of the article >>>

Big bacteria with lots of DNA

Size matters.

That's why there are no insects as big as horses [*], or bacteria as large as to be seen without the use of a microscope. Well, actually, the latter is not true —although a typical bacterial cell is not longer than 5 micrometers, a few species such as Thiomargarita namibiensis (left image) and Epulopiscium fishelsoni may reach a length of over 0.5 millimeters (500 micrometers); enough to become visible to the naked eye.

Big bacteria enjoy some advantages; for instance, they can not be swallowed by most predators (such as ciliates) that feed on smaller cells. But they also face important problems, especially those related to diffusion limitation. In general, bacteria obtain their food molecules by diffusion; for this reason, their cells need to maintain a high surface-to-volume ratio. Thiomargarita solves this problem by creating a huge central vacuole that fills about 98% of the cell volume, leaving only a thin layer of cytoplasm lining the cell wall. However, Epulopiscium appears to have a low surface-to-volume ratio (despite the presence of many invaginations of its cell membrane). This anomaly might be partially explained by the fact that Epulopiscium lives in the gut of a tropical fish, presumably a very rich medium (that is, a high concentration of nutrients may compensate their poor diffusion into a big cell). Additionally, this bacterium has some peculiarities that may be related to this issue: it reproduces by forming internal daughter cells (see figure below), and most of its DNA is arranged around the periphery of the cytoplasm.


Remarkably, a recent article published on PNAS reports that each Epulopiscium cell has tens of thousands of copies of the genome. Because so far nobody has been able to culture Epulopiscium, the authors had to collect some tropical fishes (Naso tonganus, a unicorn fish) on reefs around Lizard Island, Australia. Then, they extracted the intestinal contents, and handpicked thousands of individual Epulopiscium cells with the aid of a microscope and a micropipettor (an automated device for pipetting microliter volumes). Finally, the researchers used quantitative PCR (Polymerase Chain Reaction) to enumerate the copy number of certain genes on individual cells and in DNA obtained from populations of cells. Epulopiscium large cells contained about 250 picograms (pg) of DNA (compare to 6 pg of DNA in a human diploid cell!), corresponding to several tens of thousands of copies of a ≈3.8 megabase genome.

Such an extraordinarily high number of genome copies per cell could be related to Epulopiscium evolution in a number of interesting ways. Given the biased distribution of DNA within the cytoplasm, these big cells might possess a functional compartmentalization. In the authors' words:

"In this way, a large bacterium could function like a microcolony, with different regions of the cell independently responding to local stimuli, which would alleviate some of the pressure to remain small for the sake of rapid intracellular diffusive transport."

The article ends with:

"The enormous, polyploid Epulopiscium cell has converged on the advantages of social microbes but with additional benefits (exceptional motility, enhanced resistance to predation) normally found in large eukaryotic microbes or multicellular organisms."

Epulopiscium: another fascinating microbe!


Original article:
Mendell, J.E., Clements, K.D., Choat, J.H., Angert, E.R. (2008). Extreme polyploidy in a large bacterium. Proceedings of the National Academy of Sciences USA, 105(18), 6730-6734. DOI: 10.1073/pnas.0707522105


Related links:

• Epulopiscium page, Angert Lab, Cornell University.
• Epulopiscium - MicrobeWiki, Kenyon College.
• MicrobeLibrary - Epulopiscium fishelsoni, American Society for Microbiology.
• Beyond Binary Fission: Some Bacteria Reproduce by Alternative Means. Microbe Magazine (March 2006).
• Thiomargarita - MicrobeWiki, Kenyon College.
  
• Fossil Caviar or Giant Bacteria?, Small Things Considered (March 3, 2007).
  
• Big Bacteria. Annu Rev Microbiol (2001) 55:105-37.

[*] Giant insects might reign if only there was more oxygen in the air, EurekAlert.

+++++++++++++++++++++++++++++++++++++++++++++++++++++++

Etymology of species names:

Epulopiscium = “guest at a fish's banquet”
(Latin epulo [sumptuous food, banquet] + piscium [of a fish])

fishelsoni = "of Fishelson"
(in honor of Lev Fishelson [Tel Aviv University, Israel], one of the discoverers of Epulopiscium)

Thiomargarita = "sulfur pearl"
(Greek thio [sulfur] + margarita [pearl])

namibiensis = "from Namibia"

(Please correct me if I'm wrong)

+++++++++++++++++++++++++++++++++++++++++++++++++++++++

Image sources:
● Thiomargarita, at the cover of Science (April 16, 1999). The photomicrograph shows three cells under polarized light (middle cell is ~0.2 mm in diameter), and the small yellow spheres are sulfur globules that are restricted to the thin outer layer of the cell. Image: Ferran Garcia-Pichel.
● Life cycle of Epulopiscium. Reprinted by permission from Macmillan Publishers Ltd: Nature Rev. Microbiol. 3, 214-224 (2005). Copyright 2005.

Read the rest of the article >>>

Anthropomicrobiology

The current issue (February 2008) of Microbiology Today includes a number of articles devoted to the microorganisms that live in our body. In an introductory article (Life on us), Robin Weiss writes:

"As an ecosystem, it has become clear that we are only part human, because a significant amount of our biomass is microbial. In demographic terms, microbes outnumber our own cells. While there are 10¹⁴ human cells in the average adult, there are probably ~10¹⁵ bacteria and >10¹⁷ viruses associated with the human body. In terms of genetic diversity and complexity, the microbial metagenome of humans may be greater than the 3×10⁹ base pairs of human DNA."

So, we are superorganisms, composed of many organisms. In fact, it seems that the collective genome of our microbial symbionts (the microbiome) may contain over 100 times as many genes as our own genome, and provides traits that humans did not need to evolve on their own (from an article in Science).

In Life on us, the author makes another thought-provoking remark:

"Thus while we share >98 % host DNA sequence similarity with the chimpanzee, the microbial and viral species that live on or on us are only ~50 % shared with the great apes."

Definitely, those tiny passengers in our bodies should have influenced our evolution. How much of our "humanity" (whatever makes us different from other apes) do we owe to our microbial cells??

*********************************************

A collection of related links (in chronological order, newest first):

• Human Microbiome Project, NIH Roadmap for Medical Research. The official overview of the project (updated Jan. 2008).
  
• NIH launches Human Microbiome Project. News release, EurekAlert! (Dec. 2007).
• Deciphering the Human Microbiome (and What It Means for Health & Medicine). An explanation for the layperson, Britannica Blog (Dec. 2007).
• The Human Microbiome Project. Insight article at Nature, describing the challenges and the possible rewards of the project, with examples (Oct. 2007).
• Friendly bacteria - we need it and it needs us. Their influence in our health (the "hygiene hypothesis", possible effects on our behavior and our mental health...). Common Ground (Sept. 2007).
• Our Microbial Menagerie, and its effects on our health. Technology Review (July-Aug. 2007).
• Gut check: Tracking the ecosystem within us. The microbes in baby poop, Biology News Net [reporting on a paper from PLoS Biology] (June 2007).
• Metagenomic Analysis of the Human Distal Gut Microbiome. Research article, Science (June 2006).
• People Are Human-Bacteria Hybrid, Wired [reporting on a paper from Nature Biotechnology] (Oct. 2004).
  

*********************************************

Etymological addendum:

Anthropomicrobiology = anthropo + microbiology
Microbiology = micro + biology
Biology = bio + logy
*********************************************

Read the rest of the article >>>

From Aladdin’s Cave to Treasure Island

For a long time, it was thought that the land of actinomycetes was... well, land. I mean, they were supposed to be terrestrial creatures, even although some of them were isolated from samples taken in sea habitats (for instance, read this article from 1958). But these "marine" bacteria, generally found in shallow waters, were quite similar to their counterparts from land. For this reason, it was assumed that any actinomycetes obtained from the sea were just wash-offs from the shore.

Now this view is changing. But how can we say if a microbe isolated from a particular sea location is a true neighbor on the block (as opposed to be just derived from a passing-by or dormant spore, coming from land)? Ideally, it should be recognized by the following criteria: its ability to grow optimally at native conditions (salinity, pressure, temperature, nutrients); demonstration that the organism is really active on location; and the recognition of particular metabolic profiles, not found in terrestrial relatives. Nowadays, the existence of truly marine actinomycetes seems to be supported by solid data.

Similarly to their terrestrial relatives, marine microbes are a rich source of bioactive metabolites (antibiotics, antitumor drugs) and enzymes with different applications. For instance, cultivation of a marine actinomycete known as Salinispora tropica yielded a number of novel metabolites, not found before. One of these compounds, salinosporamide A, has antitumor properties and is currently being tested in humans for the treatment of cancer. Sequencing the genome of Salinispora tropica unveiled a number of genes coding for the synthesis of 17 potential metabolites; most of these compounds had not been detected in previous culturing of the microbe. Then, the researchers used the genetic information to guide a new chemical analysis of Salinispora cultures. The analysis uncovered an additional, novel compound (salinilactam), which had a structure corresponding to that deduced from the DNA sequence.

Let me finish with David Hopwood's words from Therapeutic treasures from the deep:

"In a recent book I likened the plethora of previously unknown genes in a newly sequenced Streptomyces genome to an Aladdin's Cave. Perhaps Treasure Island would be a more apt metaphor in this case [Salinispora]"

Neat.


List of links:
- Article from 1958: Grein A, Meyers SP, Growth characteristics and antibiotic production of actinomycetes isolated from littoral sediments and materials suspended in sea water. J. Bacteriol. 1958, 76, 457-463.
- Marine actinomycetes: Bull AT, Stach JE, Ward AC, Goodfellow M, Marine actinobacteria: perspectives, challenges, future directions. Antonie Van Leeuwenhoek, 2005, 87, 65-79.
- Salinosporamide A: Wikipedia.
- Sequencing the genome of Salinispora tropica: Udwary DW, Zeigler L, Asolkar RN, Singan V, Lapidus A, Fenical W, Jensen PR, Moore BS, Genome sequencing reveals complex secondary metabolome in the marine actinomycete Salinispora tropica. Proc. Natl. Acad. Sci. USA, 2007 , 104, 10376-10381.
- Therapeutic treasures from the deep: Hopwood DA, Nat. Chem. Biol. 2007, 3, 457-458.
- Aladdin's Cave: Aladdin - Wikipedia.
- Treasure Island: Wikipedia.


Images:
Left, Aladdin in the Magic Garden, an illustration by Max Liebert for Ludwig Fulda's Aladin und die Wunderlampe. Source: Wikipedia.
Right, Jim Hawkins and the treasure of Treasure Island, an illustration by Georges Roux for the 1885 edition of Treasure Island by Robert Louis Stevenson. Source: Wikipedia.

*****************************************************
This post is my contribution to Microbial Week, a collection of posts highlighting the many roles of microbes in deep-sea or marine environments. The event is organized by Christina Kellogg and the guys at Deep-Sea News.
*****************************************************

Read the rest of the article >>>