The loop 5 element structurally and kinetically coordinates dimers of the human kinesin-5, Eg5

Eg5 is a homotetrameric kinesin-5 motor protein that generates outward force on the overlapping, antiparallel microtubules (MTs) of the mitotic spindle. Upon binding an MT, an Eg5 dimer releases one ADP molecule, undergoes a slow (∼0.5 s⁻¹) isomerization, and finally releases a second ADP, adopting a tightly MT-bound, nucleotide-free (APO) conformation. This conformation precedes ATP binding and stepping. Here, we use mutagenesis, steady-state and pre-steady-state kinetics, motility assays, and electron paramagnetic resonance spectroscopy to examine Eg5 monomers and dimers as they bind MTs and initiate stepping. We demonstrate that a critical element of Eg5, loop 5 (L5), accelerates ADP release during the initial MT-binding event. Furthermore, our electron paramagnetic resonance data show that L5 mediates the slow isomerization by preventing Eg5 dimer heads from binding the MT until they release ADP. Finally, we find that Eg5 having a seven-residue deletion within L5 can still hydrolyze ATP and move along MTs, suggesting that L5 is not required to accelerate subsequent steps of the motor along the MT. Taken together, these properties of L5 explain the kinetic effects of L5-directed inhibition on Eg5 activity and may direct further interventions targeting Eg5 activity.     

Characterization of sarcoplasmic reticulum Ca2+ ATPase nucleotide binding domain mutants using NMR spectroscopy

T-type Ca²⁺ channels have been implicated in tremorogenesis and motor coordination. The α1 subunit of the Ca_V3.1 T-type Ca²⁺ channel is highly expressed in motor pathways in the brain, but knockout of the Ca_V3.1 gene (α1G^-/-) per se causes no motor defects in mice. Thus, the role of Ca_V3.1 channels in motor control remains obscure in vivo. Here, we investigated the effect of the Ca_V3.1 knockout in the null genetic background of α1 GABA_A receptor (α1^−/−) by generating the double mutants (α1^−/−/α1G^-/-). α1^−/−/α1G^-/- mice showed severer motor abnormalities than α1^−/− mice as measured by potentiated tremor activities at 20 Hz and impaired motor learning. Propranolol, an anti-ET drug that is known to reduce the pathologic tremor in α1^−/− mice, was not effective for suppressing the potentiated tremor in α1^−/−/α1G^-/- mice. In addition, α1^−/−/α1G^-/- mice showed an age-dependent loss of cerebellar Purkinje neurons. These results suggest that α1^−/−/α1G^-/- mice are a novel mouse model for a distinct subtype of ET in human and that Ca_V3.1 T-type Ca²⁺ channels play a role in motor coordination under pathological conditions.     

Altered versican cleavage in ADAMTS5 deficient mice; a novel etiology of myxomatous valve disease

In fetal valve maturation the mechanisms by which the relatively homogeneous proteoglycan-rich extracellular matrix (ECM) of endocardial cushions is replaced by a specialized and stratified ECM found in mature valves are not understood. Therefore, we reasoned that uncovering proteases critical for ‘remodeling’ the proteoglycan rich (extracellular matrix) ECM may elucidate novel mechanisms of valve development. We have determined that mice deficient in ADAMTS5, (A Disintegrin-like And Metalloprotease domain with ThromboSpondin-type 1 motifs) which we demonstrated is expressed predominantly by valvular endocardium during cardiac valve maturation, exhibited enlarged valves. ADAMTS5 deficient valves displayed a reduction in cleavage of its substrate versican, a critical cardiac proteoglycan. In vivo reduction of versican, in Adamts5^−/− mice, achieved through Vcan heterozygosity, substantially rescued the valve anomalies. An increase in BMP2 immunolocalization, Sox9 expression and mesenchymal cell proliferation were observed in Adamts5^−/− valve mesenchyme and correlated with expansion of the spongiosa (proteoglycan-rich) region in Adamts5^−/− valve cusps. Furthermore, these data suggest that ECM remodeling via ADAMTS5 is required for endocardial to mesenchymal signaling in late fetal valve development. Although adult Adamts5^−/− mice are viable they do not recover from developmental valve anomalies and have myxomatous cardiac valves with 100% penetrance. Since the accumulation of proteoglycans is a hallmark of myxomatous valve disease, based on these data we hypothesize that a lack of versican cleavage during fetal valve development may be a potential etiology of adult myxomatous valve disease.     

Genetic disruption of protein phosphatase 5 in mice prevents high-fat diet feeding-induced weight gain

The role of serine/threonine protein phosphatase 5 (PP5) in the development of obesity and insulin resistance associated with high-fat diet-feeding (HFD) was examined using PP5-deficient mice (Ppp5c^−/−). Despite similar caloric intake, Ppp5c^−/− mice on HFD gained markedly less weight and did not accumulate visceral fat compared to wild-type littermates (Ppp5c^+/+). On a control diet, Ppp5c^−/− mice had markedly improved glucose control compared to Ppp5c^+/+ mice, an effect diminished by HFD. However, even after 10 weeks of HFD glucose control in Ppp5c^−/− mice was similar to that observed in Ppp5c^+/+ mice on the control diet. Thus, PP5 deficiency confers protection against HFD-induced weight gain in mice.     

Early lethality of β-1,4-galactosyltransferase V-mutant mice by growth retardation

The β-1,4-galactosyltransferase (β-1,4-GalT) V whose human and mouse genes were cloned by us has been suggested to be involved in the biosynthesis of N-glycans and O-glycans, and lactosylceramide. To determine its biological function, β-1,4-GalT V (B4galt5) mutant mice obtained by a gene trap method were analyzed. Analysis of pre- and post-implantation embryos revealed that the B4galt5^−/− mice die by E10.5 while B4galt5^+/− mice were born and grown normally. Histological study showed that most tissues are formed in B4galt5^−/− embryos but their appearance at E10.5 is close to that of B4galt5^+/− embryos at E9.0-9.5. The results indicate that the growth is delayed by one to one and half day in B4galt5^−/− embryos when compared to B4galt5^+/− embryos, which results in early death of the embryos by E10.5, probably due to hematopoietic and/or placental defects.     

The mineral dissolution function of osteoclasts is dispensable for hypertrophic cartilage degradation during long bone development and growth

During long bone development and post-natal growth, the cartilaginous model of the skeleton is progressively replaced by bone, a process known as endochondral ossification. In the primary spongiosa, osteoclasts degrade the mineralized cartilage produced by hypertrophic chondrocytes to generate cartilage trabeculae that osteoblasts embed in bone matrix. This leads to the formation of the trabecular bone network of the secondary spongiosa that will undergo continuous remodeling. Osteoclasts are specialized in mineralized tissue degradation, with the combined ability to solubilize hydroxyapatite and to degrade extracellular matrix proteins. We reported previously that osteoclasts lacking Dock5 could not degrade bone due to abnormal podosome organization and absence of sealing zone formation. Consequently, adult Dock5^−/− mice have increased trabecular bone mass. We used Dock5^−/− mice to further investigate the different functions of osteoclast during endochondral bone formation. We show that long bones are overall morphologically normal in developing and growing Dock5^−/− mice. We demonstrate that Dock5^−/− mice also have normal hypertrophic cartilage and cartilage trabecular network. Conversely, trabecular bone volume increased progressively in the secondary spongiosa of Dock5^−/− growing mice as compared to Dock5^+/+ animals, even though their osteoclast numbers were the same. In vitro, we show that Dock5^−/− osteoclasts do present acidic compartments at the ventral plasma membrane and produce normal amounts of active MMP9, TRAP and CtsK for matrix protein degradation but they are unable to solubilize minerals. These observations reveal that contrarily to bone resorption, the ability of osteoclasts to dissolve minerals is dispensable for the degradation of mineralized hypertrophic cartilage during endochondral bone formation.     

Temporary upregulation of anti-inflammatory cytokine IL-13 expression in the brains of CD14 deficient mice in the early stage of prion infection

CD14 deficient (CD14^−/−) mice survived longer than wild-type (WT) C57BL/6J mice when inoculated with prions intracerebrally, accompanied by increased expression of anti-inflammatory cytokine IL-10 by microglia in the early stage of infection. To assess the immune regulatory effects of CD14 in detail, we compared the gene expression of pro- and anti-inflammatory cytokines in the brains of WT and CD14^−/− mice infected with the Chandler strain. Gene expression of the anti-inflammatory cytokine IL-13 in prion-infected CD14^−/− mice was temporarily upregulated at 75 dpi, whereas IL-13 gene expression was not upregulated in prion-infected WT mice. Immunofluorescence staining showed that IL-13 was mainly expressed in neurons of the thalamus at 75 dpi. These results suggest that CD14 can suppress IL-13 expression in neurons during the early stage of prion infection.     

Transient impairment of the adaptive response to fasting in FXR-deficient mice

The farnesoid X receptor (FXR) has been suggested to play a role in gluconeogenesis. To determine whether FXR modulates the response to fasting in vivo, FXR-deficient (FXR^−/−) and wild-type mice were submitted to fasting for 48 h. Our results demonstrate that FXR modulates the kinetics of alterations of glucose homeostasis during fasting, with FXR^−/− mice displaying an early, accelerated hypoglycaemia response. Basal hepatic glucose production rate was lower in FXR^−/− mice, together with a decrease in hepatic glycogen content. Moreover, hepatic PEPCK gene expression was transiently lower in FXR^−/−mice after 6 h of fasting and was decreased in FXR^−/−hepatocytes. FXR therefore plays an unexpected role in the control of fuel availability upon fasting.     

Macrophage ABCA5 deficiency influences cellular cholesterol efflux and increases susceptibility to atherosclerosis in female LDLr knockout mice

Objectives

To determine the role of macrophage ATP-binding cassette transporter A5 (ABCA5) in cellular cholesterol homeostasis and atherosclerotic lesion development.

Methods and results

Chimeras with dysfunctional macrophage ABCA5 (ABCA5^−M/−M) were generated by transplantation of bone marrow from ABCA5 knockout (ABCA5^−/−) mice into irradiated LDLr^−/− mice. In vitro, bone marrow-derived macrophages from ABCA5^−M/−M chimeras exhibited a 29% (P < 0.001) decrease in cholesterol efflux to HDL, whereas a 21% (P = 0.07) increase in cholesterol efflux to apoA-I was observed. Interestingly, expression of ABCA1, but not ABCG1, was up-regulated in absence of functional ABCA5 in macrophages. To induce atherosclerosis, the transplanted LDLr^−/− mice were fed a high-cholesterol Western-type diet (WTD) for 6, 10, or 18 weeks, allowing analysis of effects on initial as well as advanced lesion development. Atherosclerosis development was not affected in male ABCA5^−M/−M chimeras after 6, 10, and 18 weeks WTD feeding. However, female ABCA5^−M/−M chimeras did develop significantly (P < 0.05) larger aortic root lesions as compared with female controls after 6 and 10 weeks WTD feeding.

Conclusions

ABCA5 influences macrophage cholesterol efflux, and selective disruption of ABCA5 in macrophages leads to increased atherosclerotic lesion development in female LDLr^−/− mice.     

OX40 ligand regulates splenic CD8 dendritic cell-induced Th2 responses in vivo

In mice, splenic conventional dendritic cells (cDCs) can be separated, based on their expression of CD8α into CD8⁻ and CD8⁺ cDCs. Although previous experiments demonstrated that injection of antigen (Ag)-pulsed CD8⁻ cDCs into mice induced CD4 T cell differentiation toward Th2 cells, the mechanism involved is unclear. In the current study, we investigated whether OX40 ligand (OX40L) on CD8⁻ cDCs contributes to the induction of Th2 responses by Ag-pulsed CD8⁻ cDCs in vivo, because OX40–OX40L interactions may play a preferential role in Th2 cell development. When unseparated Ag-pulsed OX40L-deficient cDCs were injected into syngeneic BALB/c mice, Th2 cytokine (IL-4, IL-5, and IL-10) production in lymph node cells was significantly reduced. Splenic cDCs were separated to CD8⁻ and CD8⁺ cDCs. OX40L expression was not observed on freshly isolated CD8⁻ cDCs, but was induced by anti-CD40 mAb stimulation for 24 h. Administration of neutralizing anti-OX40L mAb significantly inhibited IL-4, IL-5, and IL-10 production induced by Ag-pulsed CD8⁻ cDC injection. Moreover, administration of anti-OX40L mAb with Ag-pulsed CD8⁻ cDCs during a secondary response also significantly inhibited Th2 cytokine production. Thus, OX40L on CD8⁻ cDCs physiologically contributes to the development of Th2 cells and secondary Th2 responses induced by Ag-pulsed CD8⁻ cDCs in vivo.     

Dynamic reorganization of Eg5 in the mammalian spindle throughout mitosis requires dynein and TPX2

Kinesin-5 is an essential mitotic motor. However, how its spatial-temporal distribution is regulated in mitosis remains poorly understood. We expressed localization and affinity purification-tagged Eg5 from a mouse bacterial artificial chromosome (this construct was called mEg5) and found its distribution to be tightly regulated throughout mitosis. Fluorescence recovery after photobleaching analysis showed rapid Eg5 turnover throughout mitosis, which cannot be accounted for by microtubule turnover. Total internal reflection fluorescence microscopy and high-resolution, single-particle tracking revealed that mEg5 punctae on both astral and midzone microtubules rapidly bind and unbind. mEg5 punctae on midzone microtubules moved transiently both toward and away from spindle poles. In contrast, mEg5 punctae on astral microtubules moved transiently toward microtubule minus ends during early mitosis but switched to plus end-directed motion during anaphase. These observations explain the poleward accumulation of Eg5 in early mitosis and its redistribution in anaphase. Inhibition of dynein blocked mEg5 movement on astral microtubules, whereas depletion of the Eg5-binding protein TPX2 resulted in plus end-directed mEg5 movement. However, motion of Eg5 on midzone microtubules was not altered. Our results reveal differential and precise spatial and temporal regulation of Eg5 in the spindle mediated by dynein and TPX2.     

Crystal structure of HsEg5 in complex with clinical candidate CK0238273 provides insight into inhibitory mechanism, potency, and specificity

HsEg5 is an important mitotic kinesin responsible for bipolar spindle formation at early mitosis. A rich body of evidence shows that inhibition of HsEg5 can result in mitotic arrest followed by cellular apoptosis. Recently identified HsEg5 inhibitor, CK0238273, exhibits potent antitumor activity and is currently in clinical trial. Here we report the cocrystal structure of the motor domain of HsEg5 in complex with CK0238273 at a 2.15 Å resolution. Compared to the previously published HsEg5-Monastrol complex structure, CK0238273 shares the same induced-fit pocket with similar allosteric inhibitory mechanism. However, CK0238273 shows better fitting to the binding pocket with 65% increase of hydrophobic interaction area than that of Monastrol. Some unique hydrophilic interactions were also observed mostly between the phenyl ring and 8-chloro on quinazolinone of CK0238273 with ARG221 and GLY217. We believe that the combination of these interactions defines the superior potency and specificity of CK0238273.     

Dynein light intermediate chains maintain spindle bipolarity by functioning in centriole cohesion

Cytoplasmic dynein 1 (dynein) is a minus end–directed microtubule motor protein with many cellular functions, including during cell division. The role of the light intermediate chains (LICs; DYNC1LI1 and 2) within the complex is poorly understood. In this paper, we have used small interfering RNAs or morpholino oligonucleotides to deplete the LICs in human cell lines and Xenopus laevis early embryos to dissect the LICs’ role in cell division. We show that although dynein lacking LICs drives microtubule gliding at normal rates, the LICs are required for the formation and maintenance of a bipolar spindle. Multipolar spindles with poles that contain single centrioles were formed in cells lacking LICs, indicating that they are needed for maintaining centrosome integrity. The formation of multipolar spindles via centrosome splitting after LIC depletion could be rescued by inhibiting Eg5. This suggests a novel role for the dynein complex, counteracted by Eg5, in the maintenance of centriole cohesion during mitosis.     

Cryptosporidium parvum: the contribution of Th1-inducing pathways to the resolution of infection in mice

The contribution of cytokines IL-12, IL-18, IL-23, and IFN-γ, and Stat1 signaling molecules involved in Th1 responses associated with host resistance to Cryptosporidium parvum infection was investigated in adult IL-12p40^−/−mice. Host resistance to C. parvum infection was assessed in different mouse strains lacking IL-12, IL-18, and IL-23 genes. We found that as in IL-12p40^−/− mice (which lack both IL-12 and IL-23), IL-12p35^−/− mice (which lack IL-12) and IL-18 deficient mice were also susceptible to infection with C. parvum. Varied levels of resistance were observed when mice were treated with cytokines like IL-18, IL-23 and IFN-γ. Mice treated with IL-12, as expected, were completely resistant to infection until day 5 post infection, and had significantly decreased (85%) parasite loads at peak infection (day 7), whereas rIL-23 had a lesser effect, decreasing parasite load by approximately 45%. Interestingly, IL-18 appears to play a significant role in initial immune response, even in the absence of IL-12, since treatment with IL-18 in IL-12p40^−/− knockout mice decreased parasite load by approximately 70%. In addition, the establishment of C. parvum infection in mice lacking the Stat1 gene demonstrated the involvement of this pathway in resolution of infection. These observations indicate a strong requirement for Th1 response in the development of immunity to C. parvum in the adult IL-12p40^−/− mice, information that will be essential to further investigate the immune responses during infections and in the development of potential vaccine candidates.     

The kinesin related motor protein, Eg5, is essential for maintenance of pre-implantation embryogenesis

Eg5 is a plus end directed kinesin related motor protein (KRP) previously shown to be involved in the assembly and maintenance of the mitotic spindle. KRPs are molecular motors capable of generating forces upon microtubules (MTs) in dividing cells and driving structural rearrangements necessary in the developing spindle. In vitro experiments demonstrate that loss of Eg5 results in cell cycle arrest and defective centrosome separation resulting in the development of monopolar spindles. Here we describe mice with a genetrap insertion in Eg5. Heterozygous mutant mice appear phenotypically normal. In contrast, embryos homozygous for the Eg5 null allele recovered at embryonic days 2.5-3.5 display signs of a proliferation defect as reduced cell numbers and failure of compaction and progression to the blastocyst stage was observed. These data, in conjunction with previous in vitro data, suggest that loss of Eg5 results in abnormal spindle structure, cell cycle arrest and thereby reduced cell proliferation of early cleavage pre-implantation embryos. These observations further support the conclusion that Eg5 is essential for cell division early in mouse development, and that maternal contribution may sustain the embryo through the maternal to zygotic transition at which point supplies of functional Eg5 are exhausted, preventing further cell cleavage.     

The transfer of maternal antigen-specific IgG regulates the development of allergic airway inflammation early in life in an FcRn-dependent manner

Asthma is a chronic inflammatory airway disease characterized by airway hyperreactivity, increased mucus production, and reversible airway contraction. Asthma is a complex genetic trait caused by environmental factors in genetically predisposed individuals. The transportation of maternal antigen-specific IgG via amniotic fluid, placenta and breast milk plays an important role in passive immunity. First, to examine whether maternal passive immunity by the transportation of antigen-specific IgG via FcRn regulates allergic airway inflammation, ovalbumin-immunized FcRn^+/− female mice were bred with FcRn^−/− male mice to evaluate the degree of ovalbumin-induced allergic airway inflammation of FcRn^−/− offspring. Maternal passive immunity regulated allergic airway inflammation in an FcRn-dependent manner. Second, to examine the role of maternal antigen-specific IgG1 injection into mothers, we intravenously injected ovalbumin-specific IgG1 into wild-type or FcRn^+/− mice immediately after they gave birth. The offspring were sensitized and challenged with ovalbumin. Antigen-specific IgG1 administered to lactating mice reduced allergic airway inflammation in their offspring in an FcRn-dependent manner. Last, to exclude the factor of maternal passive immunity other than ovalbumin-specific IgG1, we administered ovalbumin-specific IgG1 orally to offspring after birth. Oral administration of ovalbumin-specific IgG1 to offspring during the lactating period prevented the development of allergic airway inflammation in an FcRn-dependent manner. These data show that the transfer of maternal antigen-specific IgG regulates the development of allergic airway inflammation early in life in an FcRn-dependent manner.     

LXRβ deficient mice have reduced hepatic insulin clearance during hyperinsulinemic euglucemic clamp

The present study addresses the insulin sensitivity in mice deficient in LXRβ (LXRβ^−/−) as well as in wild type (wt) mice assessed by hyperinsulinemic euglycemic clamp. Wt and LXRβ^−/− mice were fed either a normal chow diet or a high fat and high cholesterol diet (HFCD), and insulin sensitivity was assessed by hyperinsulinemic euglycemic clamps. We show that LXRβ^−/− mice have reduced insulin clearance during hyperinsulinemic clamps upon feeding both HFCD and a regular chow diet. Moreover we also observed reduced hepatic inflammation in LXRβ^−/− mice compared to wt mice upon feeding an HFCD, despite equal levels of hepatic steatosis. In summary, our results indicate that LXRβ^−/− mice have reduced insulin clearance during hyperinsulinemic euglycemic clamps and also reduced hepatic inflammation upon feeding an HFCD for 26 weeks.     

Lymphatic vessel assembly is impaired in Aspp1-deficient mouse embryos

We previously identified apoptosis stimulating protein of p53 (Aspp1) as an endothelial-specific gene functioning in mouse embryogenesis. To investigate the in vivo role of Aspp1, we generated Aspp1 knockout mice by targeted disruption. Aspp1^−/− embryos showed subcutaneous edema and disorganized lymphatic vasculature. Morphological changes in lymphatic endothelial cells and isolated lymphatic islands were detected in Aspp1^−/− embryos. Lymphangiography by injecting dye subcutaneously into the embryonic forelimb showed defective lymphatic drainage function and obstruction in collecting lymphatic vessels of Aspp1^−/− embryos. Interestingly, Aspp1^−/− adult mice resolved these lymphatic functional defects seen during embryogenesis, but lymphangiography in Aspp1^−/− adult mice revealed abnormal patterns in collecting lymphatic vessels. Since Aspp proteins reportedly enhance apoptotic activity of p53, we asked whether p53 deficiency also affected lymphatic vessel development. Analysis of p53 knockout or Aspp1; p53 double knockout mice showed that p53 loss did not affect lymphatic vessels. These results indicate that Aspp1 plays a crucial role in the initial assembly and function of lymphatic vessels during mouse development in a p53-independent manner. Here we report novel lymphatic vascular phenotypes in Aspp1^−/− mice; subcutaneous edema detected only during embryogenesis, delayed lymphatic vessel formation, and mispatterned collecting lymphatic vessels.