Central Nervous System Imprinting of the G Protein Gsα and Its Role in Metabolic Regulation

In Albright hereditary osteodystrophy, a monogenic obesity disorder linked to heterozygous mutations of G_sα, the G protein that mediates receptor-stimulated cAMP generation, obesity develops only when the mutation is on the maternal allele. Likewise, mice with maternal (but not paternal) germline G_sα mutation develop obesity, insulin resistance, and diabetes. These parent-of-origin effects are due to G_sα imprinting, with preferential expression from the maternal allele in some tissues. As G_sα is ubiquitously expressed, the tissue involved in this metabolic imprinting effect is unknown. Using brain-specific G_sα knockout mice, we show that G_sα imprinting within the central nervous system underlies these effects and that G_sα is imprinted in the paraventricular nucleus of the hypothalamus. Maternal G_sα mutation impaired melanocortin stimulation of energy expenditure but did not affect melanocortin's effect on food intake, suggesting that melanocortins may regulate energy balance in the central nervous system through both G_sα-dependent and -independent pathways.     

Impulsive choices in mice lacking imprinted Nesp55

Genomic imprinting is the process whereby germline epigenetic events lead to parent‐of‐origin specific monallelic expression of a number of key mammalian genes. The imprinted gene Nesp is expressed from the maternal allele only and encodes for Nesp55 protein. In the brain, Nesp55 is found predominately in discrete areas of the hypothalamus and midbrain. Previously, we have shown that loss of Nesp55 gives rise to alterations in novelty‐related behaviour. Here, we extend these findings and demonstrate, using the Nesp^m/+ mouse model, that loss of Nesp55 leads to impulsive choices as measured by a delayed‐reinforcement task, whereby Nesp^m/+ mice were less willing to wait for a delayed, larger reward, preferring instead to choose an immediate, smaller reward. These effects were highly specific as performance in another component of impulsive behaviour, the ability to stop a response once started as assayed in the stop‐signal reaction time task, was equivalent to controls. We also showed changes in the serotonin system, a key neurotransmitter pathway mediating impulsive behaviour. First, we demonstrated that Nesp55 is co‐localized with serotonin and then went on to show that in midbrain regions there were reductions in mRNA expression of the serotonin‐specific genes Tph2 and Slc6a4, but not the dopamine‐specific gene Th in Nesp^m/+ mice; suggesting an altered serotonergic system could contribute, in part, to the changes in impulsive behaviour. These data provide a novel mode of action for genomic imprinting in the brain and may have implications for pathological conditions characterized by maladaptive response control.     

Bacterial expression and one-step purification of an isotope-labeled heterotrimeric G-protein α-subunit

Heterologous expression systems are often employed to generate sufficient quantities of isotope-labeled proteins for high-resolution NMR studies. Recently, the interaction between the prodomain region of subtilisin and an active, mutant form of the mature enzyme has been exploited to develop a cleavable affinity tag fusion system for one-step generation and purification of full-length soluble proteins obtained by inducible prokaryotic expression. As a first step towards applying high-resolution NMR methods to study heterotrimeric G-protein α-subunit (G_α) conformation and dynamics, the utility of this subtilisin prodomain fusion system for expressing and purifying an isotope-labeled G_α chimera (∼40 kDa polypeptide) has been tested. The results show that a prodomain fused G_α chimera can be expressed to levels approaching 6–8 mg/l in minimal media and that the processed, mature protein exhibits properties similar to those of G_α isolated from natural sources. To assay for the functional integrity of the purified G_α chimera at NMR concentrations and probe for changes in the structure and dynamics of G_α that result from activation, ¹⁵N-HSQC spectra of the GDP/Mg²⁺ bound form of G_α obtained in the absence and presence of aluminum fluoride, a well known activator of the GDP bound state, have been acquired. Comparisons of the ¹⁵N-HSQC spectra reveals a number of changes in chemical shifts of the ¹HN, ¹⁵N crosspeaks that are discussed with respect to expected changes in the protein conformation associated with G_α activation.     

Cloning and characterization of an mRNA encoding a novel G protein α-subunit abundant in mantle and gill of pearl oyster Pinctada fucata

Nacre formation is an ideal model to study biomineralization processes. Although much has been done about biomineralization mechanism of nacre, little is known as to how cellular signaling regulates this process. We are interested in whether G protein signaling plays a role in mineralization. Degenerate primers against conserved amino acid regions of G proteins were employed to amplify cDNA from the pearl oyster Pinctada fucata. As a result, the cDNA encoding a novel G_sα (pfG_sα) from the pearl oyster was isolated. The G_sα cDNA encodes a polypeptide of 377 amino acid residues, which shares high similarity to the octopus (Octopus vulgaris) G_sα. The well-conserved A, C, G (switch I), switch II functional domains and the carboxyl terminus that is a critical site for interaction with receptors are completely identical to those from other mollusks. However, pfG_sα has a unique amino acid sequence, which encodes switch III and interaction sites of adenylyl cyclase respectively. In situ hybridization and Northern blotting analysis revealed that the oyster G_sα mRNA is widely expressed in a variety of tissues, with highest levels in the outer fold of mantle and epithelia of gill, the regions essential for biomineralization. We also show that overexpression of the pfG_sα in mammalian MC3T3-E1 cells resulted in increased cAMP levels. Mutant pfG_sα that has impaired CTX substrate diminished its ability to induce cAMP production. Furthermore, the alkaline phosphatase (ALP) activity, an indicator for mineralization, is induced by the G_sα in MC3T3-E1 cells. These results indicated that G_sα may be involved in regulation of physiological function, particularly in biological biomineralization.     

Human-Xenopus chimeras of Gsα reveal a new region important for its activation of adenylyl cyclase

G proteins are heterotrimeric GTPases that play a key role in signal transduction. The α subunit of G_s bound to GTP is capable of activating adenylyl cyclase. The amino acid sequences derived from two X. laevis cDNA clones that apparently code for G_sα subunits are 92% identical to those found in the short form of human G_sα. Despite this high homology, the X. laevis G_sα clones expressed in vitro, yielded a protein that are not able to activate the adenylyl cyclase present in S49 cyc⁻ membranes in contrast with human G_sα similarly expressed. This finding suggested that the few amino acid substitutions found in the amphibian subunit are important in defining the functionality of the human G_sα. The construction of chimeras composed of different fractions of the cDNAs of the two species was adopted as an approach in determining the regions of the molecule important in its functionality in this assay. Four pairs of chimeras were constructed using reciprocal combinations of the cDNAs coding for human and Xenopus G_sα. These eight constructs were expressed in vitro and equivalent amounts of the resulting proteins were assayed in the activation of adenylyl cyclase with GTPγs and isoproterenol. The results obtained here clearly indicate that the Gα sequence that extends from amino acid 70 to 140, is important for the functionality of human G_sα in activating adenylyl cyclase.     

Identification of tubulin isoforms in different tissues of Ascaris suum using anti-tubulin monoclonal antibodies

Three monoclonal antibodies specific to α- and β-tubulin were used to examine the expression of tubulin isofoms in the intestine, reproductive tract and body wall muscle of A. suum. The tubulins were found to be different in their isoelectric points, number of isoforms and peptide maps with Western blot analysis of one-dimensional polyacrylamide gel confirming the presence of α-, β₁- and β₂- tubulin. Commercial cross-reactive anti-α and anti-β MAbs 356 and 357 recognized tubulin from A. suum tissues as well as from pig brain, whereas anti-A. suum β-tubulin specific MAb P3D6 recognized tubulin from the A. suum tissues only. Two-dimensional gel analysis showed different isoform patterns in different A. suum tissues with anti-A. suum β-tubulin MAb P3D6 and cross-reactive β-tubulin MAb 357 recognizing 2–4 β- tubulin isoforms and anti-α-tubulin MAb 356 recognizing 1–6 α-tubulin isoforms. Different peptide maps of tubulin were observed in the three tissues, when subjected to limited proteolysis followed by SDS-PAGE. The data indicate that different tubulins are found in different tissues of adult A. suum.     

A Mouse Model for Osseous Heteroplasia

GNAS/Gnas encodes G_sα that is mainly biallelically expressed but shows imprinted expression in some tissues. In Albright Hereditary Osteodystrophy (AHO) heterozygous loss of function mutations of GNAS can result in ectopic ossification that tends to be superficial and attributable to haploinsufficiency of biallelically expressed G_sα. Oed-Sml is a point missense mutation in exon 6 of the orthologous mouse locus Gnas. We report here both the late onset ossification and occurrence of benign cutaneous fibroepithelial polyps in Oed-Sml. These phenotypes are seen on both maternal and paternal inheritance of the mutant allele and are therefore due to an effect on biallelically expressed G_sα. The ossification is confined to subcutaneous tissues and so resembles the ossification observed with AHO. Our mouse model is the first with both subcutaneous ossification and fibroepithelial polyps related to G_sα deficiency. It is also the first mouse model described with a clinically relevant phenotype associated with a point mutation in G_sα and may be useful in investigations of the mechanisms of heterotopic bone formation. Together with earlier results, our findings indicate that G_sα signalling pathways play a vital role in repressing ectopic bone formation.     

Increased plasticity of genomic imprinting of Dlk1 in brain is due to genetic and epigenetic factors

The expression of six imprinted genes (Dlk1, Gtl2, Igf2r, Kcnq1, Nnat, and Peg1) was examined in brains of 21 mice derived from N₂ × N₂ intercrosses between C57BL/6 and MOLF/Ei strains. Imprinting of Igf2r, Kcnq1, Gtl2, and Dlk1 varied among individuals. As three of these genes are implicated in cell–cell signaling or cell–environment interactions, variation in their imprinting may influence a wide range of biological processes from cell differentiation to behavior. To elucidate the mechanisms underlying the interindividual imprinting variation in the brain, we focused our effort on the paternally expressed gene Dlk1. We investigated expression of Dlk1 in the brains of animals from N₉ and N₁₀ backcrosses and found that reactivation of the normally silent maternal Dlk1 allele in the N₉ and N₁₀ mice occurred less often than in N₂ × N₂ animals. Our data suggest that trans-acting genetic factors of MOLF/Ei origin facilitate the reactivation of the normally silent maternal allele of Dlk1. We mapped one of these factors to the proximal part of Chr 7. The results of bisulfite sequencing methylation analysis show that reactivation of the maternal allele was also associated with hypermethylation of the intragenic differentially methylated region (IG DMR), which is the imprinting control region for the Dlk1–Gtl2 domain. Thus, the imprinting status of Dlk1 in the brain depends upon trans-acting genetic influences and correlates with the methylation status of a specific subregion of the IG DMR.The GenBank accession numbers for sequences described in this article are AY644388–644394.     

A Region Containing a Proline-Rich Motif Targets sGi2 to the Golgi Apparatus

The central function of heterotrimeric GTP-binding proteins (G proteins) is the transduction of extracellular signals, via membrane receptors, leading to the activation of intracellular effectors. In addition to being associated with the plasma membrane, the α subunits of some of these proteins have also been localized in intracellular compartments. The mRNA of the G-protein inhibitory α subunit 2 (G_αi2) encodes two proteins, G_αi2 and sG_i2, by an alternative splicing mechanism. sG_i2 differs from G_αi2 in the C-terminal region and localizes in the Golgi in contrast to the plasma membrane localization of G_αi2. In this paper we show that the sequence specific to sG_i2 can direct the Golgi localization of other G_αi subunits, but not of the stimulatory subunit G_αs or of a secreted protein. This indicates that, in addition to the sG_i2 C-terminus, sequences located elsewhere in the protein are required to determine the Golgi localization. Inside the sG_i2 C-terminal region we have identified a 14-amino-acid proline-rich motif which specifies the Golgi localization. Finally, we show that the sG_i2 subunit, once activated, leaves the Golgi to be localized in the endoplasmic reticulum.