Lineage-specific positive selection at the merozoite surface protein 1 (msp1) locus of Plasmodium vivax and related simian malaria parasites.

BACKGROUND: The 200 kDa merozoite surface protein 1 (MSP-1) of malaria parasites, a strong vaccine candidate, plays a key role during erythrocyte invasion and is a target of host protective immune response. Plasmodium vivax, the most widespread human malaria parasite, is closely related to parasites that infect Asian Old World monkeys, and has been considered to have become a parasite of man by host switch from a macaque malaria parasite. Several Asian monkey parasites have a range of natural hosts. The same parasite species shows different disease manifestations among host species. This suggests that host immune responses to P. vivax-related malaria parasites greatly differ among host species (albeit other factors). It is thus tempting to invoke that a major immune target parasite protein such as MSP-1 underwent unique evolution, depending on parasite species that exhibit difference in host range and host specificity. RESULTS: We performed comparative phylogenetic and population genetic analyses of the gene encoding MSP-1 (msp1) from P. vivax and nine P. vivax-related simian malaria parasites. The inferred phylogenetic tree of msp1 significantly differed from that of the mitochondrial genome, with a striking displacement of P. vivax from a position close to P. cynomolgi in the mitochondrial genome tree to an outlier of Asian monkey parasites. Importantly, positive selection was inferred for two ancestral branches, one leading to P. inui and P. hylobati and the other leading to P. vivax, P. fieldi and P. cynomolgi. This ancestral positive selection was estimated to have occurred three to six million years ago, coinciding with the period of radiation of Asian macaques. Comparisons of msp1 polymorphisms between P. vivax, P. inui and P. cynomolgi revealed that while some positively selected amino acid sites or regions are shared by these parasites, amino acid changes greatly differ, suggesting that diversifying selection is acting species-specifically on msp1. CONCLUSIONS: The present results indicate that the msp1 locus of P. vivax and related parasite species has lineage-specific unique evolutionary history with positive selection. P. vivax and related simian malaria parasites offer an interesting system toward understanding host species-dependent adaptive evolution of immune-target surface antigen genes such as msp1.

Colocalization of a carnosine-splitting enzyme, tissue carnosinase (CN2)/cytosolic non-specific dipeptidase 2 (CNDP2), with histidine decarboxylase in the tuberomammillary nucleus of the hypothalamus.

Carnosine is a naturally occurring dipeptide (beta-alanyl-l-histidine) present in mammalian tissues such as the brain and skeletal muscles. Carnosine is not only a radical scavenger but also a possible neurotransmitter-like molecule that regulates neuronal functions such as hypothalamic control of the autonomic nervous system. CN2 (CNDP2) is a cytosolic enzyme that can hydrolyze carnosine to yield l-histidine and beta-alanine. In order to understand the functions of carnosine and CN2 in the brain, we have investigated the immunohistochemical localization of CN2 in the hypothalamus. CN2-immunoreactivity was highly concentrated in neuronal cells in the dorsal part of the tuberomammillary nucleus of the posterior hypothalamus. Since the tuberomammillary nucleus is the exclusive origin of histaminergic neurons, we further investigated whether CN2 is present in the histaminergic neurons. We found that CN2-immunoreactivity was colocalized with that of histidine decarboxylase, which is the key enzyme for histamine biosynthesis specifically expressed in the histaminergic neurons of the tuberomammillary nucleus. These results suggest that CN2 is highly expressed in the histaminergic neurons in the tuberomammillary nucleus, implying that it may supply histidine to histaminergic neurons for histamine synthesis.

Big bang in the evolution of extant malaria parasites.

Malaria parasites (genus Plasmodium) infect all classes of terrestrial vertebrates and display host specificity in their infections. It is therefore assumed that malaria parasites coevolved intimately with their hosts. Here, we propose a novel scenario of malaria parasite-host coevolution. A phylogenetic tree constructed using the malaria parasite mitochondrial genome reveals that the extant primate, rodent, bird, and reptile parasite lineages rapidly diverged from a common ancestor during an evolutionary short time period. This rapid diversification occurred long after the establishment of the primate, rodent, bird, and reptile host lineages, which implies that host-switch events contributed to the rapid diversification of extant malaria parasite lineages. Interestingly, the rapid diversification coincides with the radiation of the mammalian genera, suggesting that adaptive radiation to new mammalian hosts triggered the rapid diversification of extant malaria parasite lineages.

Structural basis for substrate recognition and hydrolysis by mouse carnosinase CN2.

L-carnosine is a bioactive dipeptide (beta-alanyl-L-histidine) present in mammalian tissues, including the central nervous system, and has potential neuroprotective and neurotransmitter functions. In mammals, two types of L-carnosine-hydrolyzing enzymes (CN1 and CN2) have been cloned thus far, and they have been classified as metallopeptidases of the M20 family. The enzymatic activity of CN2 requires Mn(2+), and CN2 is inhibited by a nonhydrolyzable substrate analog, bestatin. Here, we present the crystal structures of mouse CN2 complexed with bestatin together with Zn(2+) at a resolution of 1.7 A and that with Mn(2+) at 2.3 A CN2 is a homodimer in a noncrystallographic asymmetric unit, and the Mn(2+) and Zn(2+) complexes closely resemble each other in the overall structure. Each subunit is composed of two domains: domain A, which is complexed with bestatin and two metal ions, and domain B, which provides the major interface for dimer formation. The bestatin molecule bound to domain A interacts with several residues of domain B of the other subunit, and these interactions are likely to be essential for enzyme activity. Since the bestatin molecule is not accessible to the bulk water, substrate binding would require conformational flexibility between domains A and B. The active site structure and substrate-binding model provide a structural basis for the enzymatic activity and substrate specificity of CN2 and related enzymes.

Effects of central injection of L-carnosine on sympathetic nerve activity innervating brown adipose tissue and body temperature in rats.

In the present study, using urethane-anesthetized rats, we examined the effects of intralateral cerebral ventricular (LCV) injection of various doses of L-carnosine on neural activity innervating brown adipose tissue (BAT-SNA) and body temperature (BT). We found that injection of a low dose of L-carnosine (0.01 microg) suppressed BAT-SNA significantly. Conversely, a high dose (100 microg) of L-carnosine significantly elevated BAT-SNA. In the light period (14:00), brown adipose tissue temperature (BAT-T) and BT were suppressed after low and elevated after high dose injection of L-carnosine whereas in the dark period (2:00), these parameters remained unchanged with L-carnosine treatment. Bilateral lesions of the hypothalamic suprachiasmatic nucleus (SCN) abolished the effects of low and high doses of L-carnosine on BAT-SNA, BAT-T and BT. Furthermore, high dose treatment with L-carnosine altered c-Fos induction in the SCN and the PVN. These results suggest that l-carnosine affects BAT-SNA, BAT-T and BT in a dose-dependent manner in the rat, and that the SCN may be involved in these effects.

Crystallization and preliminary crystallographic study of carnosinase CN2 from mice.

Mammalian tissues contain several histidine-containing dipeptides, of which L-carnosine is the best characterized and is found in various tissues including the brain and skeletal muscles. However, the mechanism for its biosynthesis and degradation have not yet been fully elucidated. Crystallographic study of carnosinase CN2 from mouse has been undertaken in order to understand its enzymatic mechanism from a structural viewpoint. CN2 was crystallized by the hanging-drop vapour-diffusion technique using PEG 3350 as a precipitant. Crystals were obtained in complex with either Mn(2+) or Zn(2+). Both crystals of CN2 belong to the monoclinic space group P2(1) and have almost identical unit-cell parameters (a = 54.41, b = 199.77, c = 55.49 A, beta = 118.52 degrees for the Zn(2+) complex crystals). Diffraction data were collected to 1.7 and 2.3 A for Zn(2+) and Mn(2+) complex crystals, respectively, using synchrotron radiation. Structure determination is ongoing using the multiple-wavelength anomalous diffraction (MAD) method.

Identification and characterization of a mouse dipeptidase that hydrolyzes L-carnosine.

L-Carnosine is a bioactive dipeptide present in mammalian tissues including the central nervous system. We have recently shown that L-carnosine is involved in the regulation of energy homeostasis through the autonomic nervous system, but the mechanisms for its biosynthesis and degradation have not yet been fully elucidated. Here we report the biochemical and immunohistochemical characterization of a mammalian protein that has a 17% overall amino acid sequence homology with a Lactobacilus carnosinase, PepV. A recombinant protein expressed in E. coli has the enzymatic ability to digest L-carnosine and various other dipeptides, and this activity is inhibited by bestatin. It requires Mn2+ for enzymatic activity and its effect is reversible. Immunohistochemical analysis showed that a few neuronal populations express this protein at very high levels. It is highly expressed in the parafascicular nucleus of the thalamus, tuberomammillary nucleus of the hypothalamus and the mitral cell layer of the olfactory bulb. In addition, neuronal processes, but not cell bodies, are stained in the striatum. In all these areas, the protein did not colocalize with the glial fibrilary acidic protein. These results suggest that a peptidase that digests L-carnosine is enriched in several specific neuronal populations in the central nervous system.

Possible role of L-carnosine in the regulation of blood glucose through controlling autonomic nerves.

Mammalian muscles synthesize L-carnosine, but its roles were unknown. Previously, we found in rats that the administration of a certain amount of L-carnosine elicited an inhibition of the hyperglycemia induced by the injection of 2-deoxy-D-glucose (2DG) into the lateral cerebral ventricle (LCV), and that intravenous injection of L-carnosine inhibited sympathetic nerves and facilitated the parasympathetic nerve. Moreover, the suppressive effect of L-carnosine on the hyperglycemia induced by 2DG was eliminated by thioperamide, a histaminergic H3 receptor. These findings suggested that L-carnosine might control the blood glucose level through regulating autonomic nerves via H3 receptor. To further clarify the function of L-carnosine, we examined its role in the control of the blood glucose. In this experiment, the following results were observed in rats: (i) A certain amount (0.01% or 0.001%) but not a larger amount (0.1%) of L-carnosine given as a diet suppressed the hyperglycemia induced by LCV-injection of 2DG (2DG-hyperglycemia); (ii) LCV-injection but not the injection into the intraperitoneal space (IP) of a certain amount of L-histidine suppressed the 2DG-hyperglycemia; (iii) treatments of diphenhydramine, an H1 antagonist, and alpha-fluoromethylhistidine, an inhibitor of histamine-synthesizing enzyme, reduced the 2DG-hyperglycemia; (iv) the plasma L-carnosine concentration and carnosinase activity showed daily changes; (v) the plasma L-carnosine concentration was significantly lower in the streptozotocin-diabetic rats; (vi) exercise by a running wheel tended to increase carnosine synthase activity in the gastrocnemius muscle and elevated the plasma L-carnosine concentration in the dark (active) period, and enhanced the plasma carnosinase activity in the light period; (vii) IP-injection of certain amount of L-carnosine stimulated the feeding response to IP-injection of 2DG. These findings suggest a possibility that L-carnosine released from muscles due to exercise functions to reduce the blood glucose level through the regulation of the autonomic nerves.

Stimulation of BIT induces a circadian phase shift of locomotor activity in rats.

Circadian rhythms of mammals are generated by a circadian oscillation of master pacemaker genes in the suprachiasmatic nucleus of the hypothalamus (SCN), and entrained by environmental factors such as 24-h light-dark cycles. We have previously shown that light exposure during the dark period enhanced tyrosine phosphorylation of brain immunoglobulin-like molecule with tyrosine-based activation motifs (BIT) in the rat SCN. To elucidate the functional roles of BIT in the circadian clock, we stimulated BIT using an anti-BIT monoclonal antibody (mAb) 1D4, which reacts with its extracellular region and induces phosphorylation of its intracellular tyrosine residues. Administration of mAb 1D4 into the third cerebral ventricle induced tyrosine phosphorylation of BIT in the SCN. Behavioral analyses showed that the SCN-injection of the antibody at CT15 induced a phase delay of the circadian rhythm of locomotor activity, and that at CT20 induced a phase advance. Pretreatment with MK801, a non-competitive antagonist of NMDARs, diminished the 1D4-induced phase shift at CT20, but not at CT15. These results suggest that BIT is involved in the entrainment of circadian rhythms through the function of NMDARs and non-NMDARs.