Perspective: the size-complexity rule

It is widely accepted that bigger entities have a greater division of labor than smaller ones and this is reflected in the fact that larger multicellular organisms have a corresponding increase in the number of their cell types. This rule is examined in some detail from very small organisms to large animals, and plants, and societies. Compared to other size-related rules, the size-complexity rule is relatively rough and approximate, yet clearly it holds throughout the whole range of living organisms, as well as for societies. The relationship between size and complexity is analyzed by examining the effects of size increase and decrease: size increase requires an increase in complexity, whereas size decrease permits, and sometimes requires, a decrease in complexity. Conversely, an increase or decrease in complexity permits, but does not require changes in size. An especially compelling argument for the close relation between size and complexity can be found in size quorum sensing in very small multicellular organisms.     

Large isoforms of UNC-89 (obscurin) are required for muscle cell architecture and optimal calcium release in Caenorhabditis elegans

Calcium, a ubiquitous intracellular signaling molecule, controls a diverse array of cellular processes. Consequently, cells have developed strategies to modulate the shape of calcium signals in space and time. The force generating machinery in muscle is regulated by the influx and efflux of calcium ions into the muscle cytoplasm. In order for efficient and effective muscle contraction to occur, calcium needs to be rapidly, accurately and reliably regulated. The mechanisms underlying this highly regulated process are not fully understood. Here, we show that the Caenorhabditis elegans homolog of the giant muscle protein obscurin, UNC-89, is required for normal muscle cell architecture. The large immunoglobulin domain-rich isoforms of UNC-89 are critical for sarcomere and sarcoplasmic reticulum organization. Furthermore, we have found evidence that this structural organization is crucial for excitation-contraction coupling in the body wall muscle, through the coordination of calcium signaling. Thus, our data implicates UNC-89 in maintaining muscle cell architecture and that this precise organization is essential for optimal calcium mobilization and efficient and effective muscle contraction.     

Control of albumin and alpha-fetoprotein expression in rat liver and in some transplantable hepatocellular carcinomas.

Albumin and alpha-fetoprotein production by rat liver and by four selected transplantable hepatocellular carcinomas is compared to the messenger RNA present in these tissues. Albumin and alpha-fetoprotein were measured by radioimmunoassay of serum concentration, immunofluorescence, and in vitro incorporation of labeled amino acids into proteins specifically precipitated by antisera. The number of mRNA molecules per cell was calculated from the hybridization of specific cDNA probes to polysomal mRNA and by translational activity of polysomal RNA in a wheat germ system. The amount of albumin and alpha-fetoprotein produced by the different tissues is directly related to the number of functional mRNA molecules per cell for each protein.     

Histone phosphorylation during liver regeneration.

The pattern of histone phosphorylation at acid-stable, alkali-labile sites has been examined throughout the early stages of liver regeneration, namely at times of “gene activation”. Among the histones, only H1 shows an increase in phosphorylation. This increase initiates near the end of the period of chromatin template activation. Thus, there is no obvious temporal correlation between increased histone phosphorylation and increased RNA synthesis. The relative levels of phosphorylation of the various histones and the change in H1 phosphorylation observed in the liver system closely parallel the patterns exhibited by cultured animal cells during the G1 and S phases of the cycle as described by other investigators.     

Biodegradation of neutralized sarin.

This research investigated the biotransformation of IMPA, the neutralization product of the nerve agent Sarin, by a microbial consortia. As mandated by the Chemical Weapons Convention signed by 132 countries in 1993, all chemical warfare agents are to be destroyed within ten years of ratification. Technologies must be developed to satisfy this commitment. This paper presents data from a biodegradation kinetics study and background information on the biological transformation of IMPA. Microbial transformation of organophosphate nerve agents and organophosphate pesticide intermediates can be incorporated into a treatment process for the fast and efficient destruction of these similar compounds. Sarin (isopropyl methylphosphonofluoridate), also known as GB, is one of several highly neurotoxic chemical warfare agents that have been developed over the past 50 to 60 years. Four mixed cultures were acclimated to the Sarin hydrolysis product, isopropyl methylphosphonic acid (IMPA). Two of these cultures, APG microorganisms and SX microorganisms, used IMPA as the sole phosphorus source. Extended exposure to IMPA improved the cultures' abilities to degrade IMPA to form methylphosphonic acid (MPA) and inorganic phosphate. The presence of free phosphate in the reactor suppressed the degradation of IMPA. IMPA did not inhibit either cultural consortia within the tested concentration range (0 to 1250 mg/L). The numax was 120.9 mg/L/day for the SX microorganisms and 118.3 mg/L/day for the APG microorganisms. Initial IMPA concentrations of 85 to 90 mg/L were degraded to nondetectable levels within 75 h. These results demonstrate the potential for biodegradation to serve as a complementary treatment process for the destruction of stockpiled Sarin.     

Terrestrial and extraterrestrial sources of molecular homochirality

The unique chirality of biomolecules is reviewed, and the prebiotic requirement for the absolute chiral homogeneity of such molecules prior to their capability of self-replication is emphasized. Biotic and abiotic theories embracing both chance and determinate mechanisms which have been proposed for the origin of terrestrial chiral molecules are briefly summarized and evaluated, as are abiotic mechanisms for the subsequent amplification of the small enantiomeric excesses (e.e.s) in the chiral molecules which might be formed by such processes. While amplification mechanisms are readily validated experimentally and are potentially viable on the primitive Earth, it is concluded that all terrestrial mechanisms proposed for the origin of chirality have one or more limitations which make them either intrinsically invalid or highly improbable in the chaotic and turbulent environment of the prebiotic Earth. To circumvent these difficulties we have proposed an extraterrestrial scenario for the production of terrestrial chirality in which circularly polarized synchrotron radiation from the neutron star remnant of a supernova interacts with the organic mantles on interstellar grains, producing chiral molecules by the partial asymmetric photolysis of racemic constituent in the mantles, after which the interstellar grains with their enantiomerically enriched mantles are transported to Earth either by direct accretion or through cometary impact. At this point one of the known terrestrial e.e. enrichment mechanisms could promote the small extraterrestrially produced e.e.s. into the state of chiral homogeneity required for self-replicating biomolecules.