Hyperinsulinemia and insulin resistance : What comes first ?

Background

1)	Classical explanation :
Classical explanation of diabetic pathophysiology states that obesity induced insulin resistance develops first and is followed by compensatory hyperinsulinnemia. Further insulin resistance leads to prolonged, increased secretary demand on beta cells leading to subsequent secondary beta cell failure, giving rise to hyperglycaemia and diabetes^2^.

2)	 Neurobehavioral origin hypothesis :
The Neurobehavioral origin hypothesis suggests that insulin resistance mediates a shift from muscle dependent (soldier) to brain dependent (diplomat) strategies of making a livelihood. If nutrient limitation affects intrauterine development, brain development is the least affected among all the organs^4,5^. As a result, in IUGR babies muscle weight is poor but the brain is relatively well developed. Such a person is more likely to be a successful diplomat rather than a soldier and insulin resistance is adaptive for such an individual^3^. Since insulin is involved in brain development and cognitive functions, higher levels of insulin are needed. As insulin is having strong anti-lipolytic effect, hyperinsulinnemia is followed by subsequent excess fat accumulation. Also compensatory insulin resistance is needed to avoid hypoglycemia. This hypothesis predicts a reverse order of pathophysiology i.e. primary hyperinsulinnemia followed by compensatory insulin resistance^3^

Objective-
To determine in diabetes whether hyperinsulinnemia develops first or insulin resistance develops first.

Methods :
We searched literature for studies that investigated directly or indirectly the sequence of development of hyperinsulinnemia and insulin resistance in humans and animal models from an early stage. Meta-analysis was conducted on published data.

Results-
1)	In low birth weight neonates in humans as well as in rat models, hyperinsulinnemia is found at very early stage.^6^
2)	Development of insulin resistance is preceded by hyperinsulinnemia in mice, rats as well as in humans.^7, 8^
3)	In normoglycaemic hyperinsulinemia state if insulin production is suppressed insulin sensitivity increases rapidly maintaining the normoglycaemic state.^9,10^
4)	Beta cell expansion beginning in intrauterine life is independent of glucose, Insulin and Insulin receptors.^6^


Conclusion-
All the four lines of evidence indicate that hyperinsulinnemia precedes insulin resistance supporting the predictions of neurobehavioral origin hypothesis over the orthodox view.



References :
1)	DeFronzo RA, Ferrannini E (1991). Diabetes Care 14:173-194
2)	Kruszynska YT, Olefsky JM (1996). J Investig Med 44: 413-428.
3)	Watve MG, Yajnik CY (2007). BMC Evolutionary Biology.7: 61-74.
 4) Winick M, Rosso P, Waterlow JC (1970). Exp Neurol, 26:393-400.
 5) Winick M. (1969) J Pediatr,74:667-679.
 6) Chakravarthy MV et.al. (2008) Diabetes, 57:2698-2707.
 7) Ramin A et. al. (1998) J Clin Endo and Met, 83 :1911-1915.
 8) Hansen BC (1990) Am J Physiol Regul Integr Comp Physiol 259: 612-617.
 9) Stanley L (1981) Life Sciences, 28: 1829-1840.
 10) Ratzmann KP et. al. (1983) Int J Obes, 7 : 453-458

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Patterns in abundance and diversity of faecally dispersed parasites of tiger in Tadoba National Park, central India

BACKGROUND: Importance of parasites in ecological and evolutionary interactions is being increasingly recognized. However, ecological data on parasites of important host species is still scanty. We analyze the patterns seen in the faecal parasites of tigers in the Tadoba National Park, India, and speculate on the factors and processes shaping the parasite community and the possible implications for tiger ecology. RESULTS: The prevalence and intensities were high and the parasite community was dominated by indirect life cycle parasites. Across all genera of parasites variance scaled with the square of the mean and there was a significant positive correlation between prevalence and abundance. There was no significant association between different types of parasites. CONCLUSIONS: The 70 samples analyzed formed 14 distinct clusters. If we assume each of the clusters to represent individual tigers that were sampled repeatedly and that resident tigers are more likely to be sampled repeatedly, the presumed transient tigers had significantly greater parasite loads than the presumed resident ones

Phenotypic Plasticity and Effects of Selection on Cell Division Symmetry in Escherichia coli

Aging has been demonstrated in unicellular organisms and is presumably due to asymmetric distribution of damaged proteins and other components during cell division. Whether the asymmetry-induced aging is inevitable or an adaptive and adaptable response is debated. Although asymmetric division leads to aging and death of some cells, it increases the effective growth rate of the population as shown by theoretical and empirical studies. Mathematical models predict on the other hand, that if the cells divide symmetrically, cellular aging may be delayed or absent, growth rate will be reduced but growth yield will increase at optimum repair rates. Therefore in nutritionally dilute (oligotrophic) environments, where growth yield may be more critical for survival, symmetric division may get selected. These predictions have not been empirically tested so far. We report here that Escherichia coli grown in oligotrophic environments had greater morphological and functional symmetry in cell division. Both phenotypic plasticity and genetic selection appeared to shape cell division time asymmetry but plasticity was lost on prolonged selection. Lineages selected on high nutrient concentration showed greater frequency of presumably old or dead cells. Further, there was a negative correlation between cell division time asymmetry and growth yield but there was no significant correlation between asymmetry and growth rate. The results suggest that cellular aging driven by asymmetric division may not be hardwired but shows substantial plasticity as well as evolvability in response to the nutritional environment

Sociobiological Control of Plasmid copy number

Background:
All known mechanisms and genes responsible for the regulation of plasmid replication lie with the plasmid rather than the chromosome. It is possible therefore that there can be copy-up mutants. Copy-up mutants will have within host selective advantage. This would eventually result into instability of bacteria-plasmid association. In spite of this possibility low copy number plasmids appear to exist stably in host populations. We examined this paradox using a computer simulation model.

Model:
Our multilevel selection model assumes a wild type with tightly regulated replication to ensure low copy number. A mutant with slightly relaxed replication regulation can act as a “cheater” or “selfish” plasmid and can enjoy a greater within-host-fitness. However the host of a cheater plasmid has to pay a greater cost. As a result, in host level competition, host cell with low copy number plasmid has a greater fitness. Furthermore, another mutant that has lost the genes required for conjugation was introduced in the model. The non-conjugal mutant was assumed to undergo conjugal transfer in the presence of another conjugal plasmid in the host cell.

Results:
The simulatons showed that if the cost of carrying a plasmid was low, the copy-up mutant could drive the wild type to extinction or very low frequencies. Consequently, another mutant with a higher copy number could invade the first invader. This process could result into an increasing copy number. However above a certain copy number within-host selection was overcompensated by host level selection leading to a rock-paper-scissor (RPS) like situation. The RPS situation allowed the coexistence of high and low copy number plasmids. The non-conjugal “hypercheaters” could further arrest the copy numbers to a substantially lower level.

Conclusions:
These sociobiological interactions might explain the stability of copy numbers better than molecular mechanisms of replication regulation alone

Myxobacterial diversity of Indian soils - How many species do we have?

Myxobacteria of tropical soils is an under-explored bacterial group. We report below the results of sampling in Pune district of Western Ghats. A number of novel morphotypes were found in forest as well as urban/semi-urban soils. There was a high level of floral dissimilarity between habitats. The morphotypes detected in Pune district also differed from the northern Indian species recorded earlier. Using a species individual curve on the Pune, Lucknow and pooled data, we try to estimate the number of species that are likely to be present in India. A plausible estimate is several fold higher than the species recorded worldwide so far

Sarcocystosis of chital-dhole: conditions for evolutionary stability of a predator parasite mutualism

<p>Abstract</p> <p>Background</p> <p>For parasites with a predator-prey life cycle, the completion of the life cycle often depends on consumption of parasitized prey by the predator. In the case of such parasite species the predator and the parasite have common interests and therefore a mutualistic relationship is possible. Some evidence of a predator-parasite mutualism was reported from spotted deer or chital (<it>Axix axis</it>) as a prey species, dhole or Indian wild-dog (<it>Cuon alpinus</it>) as the predator and a protozoan (<it>Sarcocystis axicuonis</it>) as the parasite. We examine here, with the help of a model, the ecological conditions necessary for the evolution and stability of such a mutualistic relationship. A two – level game theory model was designed in which the payoff of a parasite is decided not only by alternative parasite strategies but also by alternative host strategies and vice versa. Conditions for ESS were examined.</p> <p>Results</p> <p>A tolerant predator strategy and a low or moderately virulent parasite strategy which together constitute mutualism are stable only at a high frequency of recycling of parasite and a substantial prey – capture benefit to the predator. Unlike the preliminary expectation, parasite will not evolve towards reduced virulence, but reach an optimum moderate level of virulence.</p> <p>Conclusion</p> <p>The available data on the behavioral ecology of dhole and chital suggest that they are likely to meet the stability criteria and therefore a predator-parasite mutualism can be stable in this system. The model also points out the gaps in the current data and could help directing further empirical work.</p

Epidemic diseases and host clustering: an optimum cluster size ensures maximum survival

The risk of infection is generally believed to increase with gregariousness. Using a discrete time spatial simulation model we tested the effect of host clustering on transmission of infection within a population. Over a large parameter range, an optimum cluster size was observed to ensure maximum probability of escaping infection. Although the within cluster transmission increased with cluster size, the between cluster distance increased thereby decreasing the probability of transmission across clusters. The probability of stochastic extinction of the pathogen also increased with increasing cluster size. Thus contrary to the popular belief, clustering can be an effective strategy to minimize the risk of infections

The maximum intra-host plasmid fitness as a function of plasmid cost.

<p>The lines show the limit of intra-host fitness above which the wild type can back invade. In presence of the non-conjugal cheaters the limit is substantially reduced. All other parameters as in <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0009328#pone-0009328-g002" target="_blank">Fig 2</a>.</p

A conceptual diagram based on generalization from many numerical results, depicting the effect of intra and inter-host fitness on realized fitness.

<p>(A) The realized fitness is a saturating function of intra-host fitness and an exponential function of inter-host fitness. As a result of the different nature of the two curves, RPS like dynamics results which is depicted schematically in (B). Arrows indicate the direction of evolutionary change. Mutants with slightly higher copy numbers can invade lower copy number plasmids owing to higher intra-host fitness. As a result the mean copy number increases, however the effect of intra-host fitness is saturating and therefore at a certain stage the reducing positive increment in realized fitness is over-compensated by increasing negative contribution of inter-host fitness difference. At this stage a low copy number plasmid can back invade resulting into a cyclic evolutionary dynamics.</p