New insights into autophagy using a multiple knockout strain

Not only is autophagy the major intracellular pathway for degradation and recycling of long-lived proteins and organelles, it is also involved in both the pathogenesis and prevention of many human diseases. Much progress has been made on the identification and characterization of AuTophaGy-related (ATG) genes, in yeast and in mammals. However, our understanding of the molecular mechanisms of autophagy remains quite limited, far from enough to harness autophagy for therapeutic applications. To better understand the molecular mechanisms, we took a unique and novel approach to study autophagy in yeast. We generated a multiple knockout Saccharomyces cerevisiae strain with 24 ATG genes deleted, and determined the minimum requirements for different aspects of autophagy. Our data also provided us with new insights into autophagy, different from those obtained from in vitro analyses. In this addendum, we briefly discuss our findings and consider fields where this multiple knockout strain can be of potential use.

Addendum to: Cao Y, Cheong H, Song H, Klionsky DJ. In vivo reconstitution of autophagy in Saccharomyces cerevisiae. J Cell Biol 2008; 182:703-13.     

Mitophagy: The Life-or-Death Dichotomy Includes Yeast

The degradation and recycling of mitochondria is an important household chore in eukaryotic cells. It is thought that mitochondrial autophagy, or mitophagy, is the major route by which mitochondria are degraded. In this view, the cell would selectively induce mitophagy to expunge malfunctioning mitochondria, thus ridding the cell of troublesome sources of reactive oxygen species, apoptosis-inducing factors, or unnecessary metabolic burden. This standard view of mitophagy, in addition to some experimental reports, points to a pro-survival role of mitophagy. However, there is also a significant amount of evidence that suggests a pro-death role of this process, some of it coming from studies in yeast. Aup1 is a protein phosphatase homolog that shows a genetic interaction with the Atg1 protein kinase, localizes to mitochondria, and is required for mitophagy under stationary phase conditions in lactate medium. In contrast with previous yeast studies on mitophagy, deletion of AUP1 results in decreased viability under mitophagy-inducing conditions, suggesting a pro-survival role under physiologically relevant conditions. Thus, the Janus-faced nature of mitophagy is conserved between yeast and mammalian systems.

Addendum to:

Aup1p, a Yeast Mitochondrial Protein Phosphatase Homolog, is Required for Efficient Stationary Phase Mitophagy and Cell Survival

R. Tal, G. Winter, N. Ecker, D.J. Klionsky and H. Abeliovich

J Biol Chem 2006; 282: 5617-24     

Harpooning the Cvt complex to the phagophore assembly site

Autophagy is a catabolic process employed by eukaryotes to degrade and recycle intracellular components. When this pathway is induced by starvation conditions, part of the cytoplasm and organelles are sequestered into double-membrane vesicles called autophagosomes, and delivered into the lysosome/vacuole for degradation. In addition to the random bulk elimination of cytoplasmic contents, the selective removal of specific cargo molecules has also been described. These selective types of autophagy are characterized by the recruitment of the cargo destined for degradation in close proximity to the forming double-membrane vesicle that results in an exclusive incorporation (that is, without bulk cytoplasm). A number of factors required for selective types of autophagy have been identified. In particular, we have recently shown that actin and the actin-binding Arp2/3 protein complex are involved in the cytoplasm to vacuole targeting (Cvt) pathway, a yeast selective type of autophagy. The contribution at a molecular level of these factors, however, remains unknown. In this addendum, we present mechanistic models that take into account possible roles of actin and the Arp2/3 complex in the Cvt pathway.

Addendum to: Monastyrska I, He C, Geng J, Hoppe D, Li Z, Klionsky DJ.Arp2 links autophagic machinery with the actin cytoskeleton. Mol Biol Cell 2008; 19:1962-75.     

Overexpression of Autophagy-Related Genes Inhibits Yeast Filamentous Growth

Under conditions of nitrogen stress, the budding yeast S. cerevisiae initiates a cellular response involving the activation of autophagy, an intracellular catabolic process for the degradation and recycling of proteins and organelles. In certain strains of yeast, nitrogen stress also drives a striking developmental transition to a filamentous form of growth, in which cells remain physically connected after cytokinesis. We recently identified an interrelationship between these processes, with the inhibition of autophagy resulting in exaggerated filamentous growth. Our results suggest a model wherein autophagy mitigates nutrient stress, and filamentous growth is responsive to the degree of this stress. Here, we extended these studies to encompass a phenotypic analysis of filamentous growth upon overexpression of autophagy-related (ATG) genes. Specifically, overexpression of ATG1, ATG3, ATG7, ATG17, ATG19, ATG23, ATG24, and ATG29 inhibited filamentous growth. From our understanding of autophagy in yeast, overexpression of these genes does not markedly affect the activity of the pathway; thus, we do not expect that this filamentous growth phenotype is due strictly to diminished nitrogen stress in ATG overexpression mutants. Rather, these results highlight an additional undefined regulatory mechanism linking autophagy and filamentous growth, possibly independent of the upstream nitrogen-sensing machinery feeding into both processes.

Addendum to:

An Interrelationship Between Autophagy and Filamentous Growth in Budding Yeast

J. Ma, R. Jin, X. Jia, C.J. Dobry, L. Wang, F. Reggiori, J. Zhu and A. Kumar

Genetics 2007; In press     

Dual role of Atg1 in regulation of autophagy-specific PAS assembly in Saccharomyces cerevisiae

Most autophagy-related (Atg) proteins are assembled at the phagophore assembly site or pre-autophagosomal structure (PAS), which is a potential site for vesicle formation during vegetative or starvation conditions. To understand the initial step of vesicle formation, it is important to know how Atg proteins are recruited to the PAS. Atg11 facilitates PAS assembly for the cytoplasm to vacuole targeting (Cvt) pathway in vegetative conditions. To examine autophagy-specific PAS formation, an ATG11 deletion mutant was used to eliminate the PAS formation that occurs in vegetative conditions. We found that Atg1, Atg13 and Atg17 play a similar role for PAS formation under autophagy-inducing conditions as seen for Atg11 during vegetative growth. In particular, Atg1 is proposed to have dual roles for autophagy-specific PAS recruitment. Atg1 plays a structural role for efficient recruitment of Atg proteins to the PAS, which is mediated by interaction with Atg13 and Atg17. In contrast, Atg1 kinase activity is needed for dissociation of Atg proteins from the PAS during autophagy inducing conditions, a function which is also critical for autophagy activity.

Addendum to: Cheong H, Nair U, Geng J Klionsky DK. The Atg1 kinase complex Is involved in the regulation of protein recruitment to initiate sequestering vesicle formation for nonspecific autophagy in Saccharomyces cerevisiae. Mol Biol Cell 2008; 19:668-81.     

Atg9 Trafficking in Yeast Saccharomyces cerevisiae

Autophagy can be divided into selective and non-selective modes. This process is considered selective when a precise cargo is specifically and exclusively incorporated into autophagosomes, the double-membrane vesicles that are the hallmark of autophagy. In contrast, during nonselective, bulk autophagy, cytoplasmic components are randomly enwrapped into autophagosomes. To date, approximately 30 autophagy-related genes called ATG have been identified. Sixteen of them compose the general basic machinery catalyzing the formation of double-membrane vesicles in all eukaryotic cells. The rest of them are often not conserved between species and cooperate with the basic Atg proteins during either selective or nonselective autophagy. Atg9 is the only integral membrane component of the conserved Atg machinery and appears to be a crucial organizational element.5 Recent studies in the S. cerevisiae have shown that Atg9 transport is differentially regulated depending on the autophagy mode. In this addendum, we will review and discuss what has recently been unveiled about yeast S. cerevisiae Atg9 trafficking, its modulators and its potential role in double-membrane vesicle biogenesis.

Addendum to:

Atg9 Sorting from Mitochondria is Impaired in Early Secretion and VFT Complex Mutants in Saccharomyces cerevisiae

F. Reggiori and D.J. Klionsky

J Cell Sci 2006: 119:2903-11     

Atg9 Trafficking in Autophagy-Related Pathways

The origin of the autophagosomal membrane and the lipid delivery mechanism during autophagy remain unsolved mysteries. Some important hints to these questions come from Atg9, which is the only integral membrane protein required for autophagosome formation and considered a membrane carrier in autophagy-related pathways. In S. cerevisiae, Atg9 cycles between peripheral sites and the preautophagosomal structure/phagophore assembly site (PAS), the nucleating site for formation of the sequestering vesicle. We recently identified a peripheral membrane protein, Atg11, as a binding partner of Atg9, in a yeast two-hybrid screen. Based on our analysis we propose a model for Atg9 cycling. Our model suggests that a pool of Atg11 mediates the anterograde transport of Atg9 to the PAS along the actin cytoskeleton, and that this delivery process may serve as a membrane shuttle for vesicle assembly during yeast selective autophagy. Here, we discuss the implications of the model and present additional evidence that extends it with regard to membrane trafficking modes during pexophagy.

Addendum to:

Recruitment of Atg9 to the Preautophagosomal Structure by Atg11 is Essential for Selective Autophagy in Budding Yeast

C. He, H. Song, T. Yorimitsu, I. Monastyrska, W.-L. Yen, J.E. Legakis and D.J. Klionsky

J Cell Biol 2006; 175:925-35     

Autophagy During Conidiation and Conidial Germination in Filamentous Fungi

Filamentous fungi form aerial hyphae on solid medium, and some of these differentiate into conidiophores for asexual sporulation (conidiation). In the filamentous deuteromycete, Aspergillus oryzae, aerial hyphae are formed from the foot cells and some differentiate into conidiophores, which are composed of vesicles, phialides and conidia. Recently, we isolated the yeast ATG8 gene homologue Aoatg8 from A. oryzae, and visualized autophagy by the expression of an EGFP (enhanced green fluorescent protein)–AoAtg8 fusion protein and DsRed2 protein in this fungus. Furthermore, by constructing the Aoatg8 deletion and conditional mutants, we demonstrated that autophagy functions during the process of differentiation of aerial hyphae, conidiation and conidial germination in A. oryzae. Here, we discuss the contribution of autophagy towards the differentiation and germination processes in filamentous fungi.

Addendum to:

Functional Analysis of the ATG8 Homologue Aoatg8 and Role of Autophagy in Differentiation and Germination in Aspergillus oryzae

T. Kikuma, M. Ohneda, M. Arioka and K. Kitamoto

Eukaryot Cell 2006; 5:1328-36     

Deletion of HOG1 Leads to Osmosensitivity in Starvation-Induced,but not Rapamycin-Dependent Atg8 Degradation and Proteolysis: Further Evidence for Different Regulatory Mechanisms in Yeast Autophagy

The mechanisms of regulation of autophagy are still obscure. In mammalian liver, starvation-induced autophagic proteolysis is regulated by the cellular hydration state in a microtubule- and p38MAPK-dependent way. Recent work shows that in yeast, loss of Hog1, the yeast orthologue of p38MAPK, leads to osmosensitivity of starvation-induced autophagy (Prick et al. Biochem J 2006; 394:153-61), pointing to an evolutionarily conserved mechanism. In this addendum further experiments from hog1delta yeast cells are shown, which support the hypothesis that starvation- and rapamycin-induced autophagy processes differ in their susceptibility to osmotic stress. The potential mechanisms are discussed.

Addendum to:

In Yeast, Loss of Hog1 Leads to Osmosensitivity of Autophagy

T. Prick, M. Thumm, K. Kohrer, D. Haussinger and S. vom Dahl

Biochem J 2006; 394:153-61     

In vivo and in vitro Leishmania amazonensis infection induces autophagy in macrophages

Autophagy is the primary mechanism of degradation of cellular proteins and at least two functions can be attributed to this biological phenomenon: increased nutrient supply via recycling of the products of autophagy under nutrient starvation; and antimicrobial response involved in the innate immune system. Many microorganisms induce host cell autophagy and it has been proposed as a pathway by which parasites compete with the host cell for limited resources. In this report we provide evidence that the intracellular parasite Leishmania amazonensis induces autophagy in macrophages. Using western blotting, the LC3II protein, a marker of autophagosomes, was detected in cell cultures with a high infection index. Macrophages infected with L. amazonensis were examined by transmission electronic microscopy, which revealed enlarged myelin-like structures typical late autophagosome and autolysosome. Other evidence indicating autophagy was Lysotracker red dye uptake by the macrophages. Autophagy also occurs in the leishmaniasis skin lesions of BALB/c mice, detected by immunohistochemistry with anti-LC3II antibody. In this study, autophagy inhibitor 3-methyladenine (3MA) reduced the infection index, while autophagy inductors, such as rapamycin or starvation, did not alter the infection index in cultivated macrophages, suggesting that one aspect of the role of autophagy could be the provision of nutritive support to the parasite.     

Autophagy-monitoring and autophagy-deficient mice

Discovery of yeast autophagy-related (ATG) genes and subsequent identification of their homologs in other organisms have enabled researchers to investigate physiological functions of macroautophagy/autophagy using genetic techniques. Specific identification of autophagy-related structures is important to evaluate autophagic activity, and specific ablation of autophagy-related genes is a critical means to determine the requirements of autophagy. Here, we review currently available mouse models, particularly focusing on autophagy (and mitophagy) indicator models and systemic autophagy-related gene-knockout mouse models.     

Atg27 is a Second Transmembrane Cycling Protein

Autophagy is a degradative pathway conserved among all eukaryotic cells, and is responsible for the turnover of damaged organelles and long-lived proteins. The primary morphological feature of autophagy is the sequestration of cargo within a double-membrane cytosolic vesicle called an autophagosome. More than 25 AuTophaGy-related (ATG) genes that are essential for autophagy have been identified from the yeast Saccharomyces cerevisiae. Despite the identification and characterization of Atg proteins, it remains a mystery how the double-membrane vesicle is made, what the membrane source(s) are, and how the lipid is transported to the forming vesicle. Among Atg proteins, Atg9 was the only characterized transmembrane protein required for the formation of double-membrane vesicles. Evidence has been obtained in yeast and mammalian cells for Atg9 cycling between different peripheral compartments and the phagophore assembly site/pre-autophagosomal structure (PAS), the proposed site of organization for autophagosome formation. This cycling feature makes Atg9 a potential membrane carrier to deliver lipids that are used in the vesicle formation process.2 Recently, in our lab we characterized a second transmembrane protein, Atg27. The unique localization and cycling features of Atg27 suggest the involvement of the Golgi complex in the autophagy pathway. In this addendum, we discuss the trafficking of Atg27 in yeast and compare it with that of Atg9, and consider the possible meaning of Atg27 Golgi localization.

Addendum to:

Atg27 is Required for Autophagy-Dependent Cycling of Atg9

W.-L. Yen, J.E. Legakis, U. Nair and D.J. Klionsky

Mol Biol Cell 2006; In press     

Maintaining T Lymphocyte Homeostasis: Another Duty of Autophagy

First identified as a pathway for nutrient recovery during periods of starvation, the role of autophagy has expanded to the clearance of “toxic” intracellular material including ubiquitin-positive protein aggregates, damaged organelles as well as microbial pathogens in various cell types. We have examined the role of autophagy in the development and function of the adaptive immune system. Genes encoding autophagy machinery are expressed in T lymphocytes, and autophagy occurs in primary CD4⁺ and CD8⁺ T cells. By generating fetal liver chimeric mice, we found that thymocyte development is largely normal but the mature T cell compartment is severely reduced in the absence of the essential autophagy gene Atg5. Consistent with a critical role for autophagy in promoting T cell survival, Atg5^-/- CD8⁺ T cells display high levels of apoptosis. Surprisingly, Atg5-deficient T cells were also unable to efficiently proliferate after T-cell receptor (TCR) stimulation. These findings suggest that autophagy regulates T lymphocyte homeostasis by promoting both survival and proliferation. In addition, T cells offer a new, physiologically relevant system to study the regulation and function of autophagy pathways in vivo.

Addendum to:

A Critical Role for the Autophagy Gene Atg5 in T Cell Survival and Proliferation

H.H. Pua, I. Dzhagalov, M. Chuck, N. Mizushima and Y.W. He

J Exp Med 2007; 204:25-31     

Small Molecule Enhancers of Rapamycin-Induced TOR Inhibition Promote Autophagy,Reduce Toxicity in Huntington’s Disease Models and Enhance Killing of Mycobacteria by Macrophages

Upregulation of autophagy may have therapeutic benefit in a range of diseases that include neurodegenerative conditions caused by intracytosolic aggregate-prone proteins, such as Huntington’s disease, and certain infectious diseases, such as tuberculosis. The best-characterized drug that enhances autophagy is rapamycin, an inhibitor of the TOR (target of rapamycin) proteins, which are widely conserved from yeast to man. Unfortunately, the side effects of rapamycin, especially immunosuppression, preclude its use in treating certain diseases including tuberculosis, which accounts for approximately 2 million deaths worldwide each year, spurring interest in finding novel drugs that selectively enhance autophagy. We have recently reported a novel two-step screening process for the discovery of such compounds. We first identified compounds that enhance the growth-inhibitory effects of rapamycin in the budding yeast Saccharomyces cerevisiae, which we termed small molecule enhancers of rapamycin (SMERs). Next we showed that three SMERs induced autophagy independently, or downstream of mTOR, in mammalian cells, and furthermore enhanced the clearance of a mutant huntingtin fragment in cell disease models. These SMERs also protected against mutant huntingtin fragment toxicity in Drosophila. We have subsequently tested two of the SMERs in models of tuberculosis and both enhance the killing of mycobacteria by primary human macrophages.

Addendum to:

Small Molecules Enhance Autophagy and Reduce Toxicity in Huntington's Disease Models

S. Sarkar, E.O. Perlstein, S. Imarisio, S. Pineau, A. Cordenier, R.L. Maglathlin, J.A. Webster, T.A. Lewis, C.J. O'Kane, S.L. Schreiber and D.C. Rubinsztein

Nat Chem Biol 2007; 3:331-8     

The tissue- and developmental stage-specific involvement of autophagy genes in aggrephagy

ABSTRACT

Genetic screens have identified two sets of genes that act at distinct steps of basal autophagy in higher eukaryotes: the pan-eukaryotic ATG genes and the metazoan-specific EPG genes. Very little is known about whether these core macroautophagy/autophagy genes are differentially employed during multicellular organism development. Here we analyzed the function of core autophagy genes in autophagic removal of SQST-1/SQSTM1 during C. elegans development. We found that loss of function of genes acting at distinct steps in the autophagy pathway causes different patterns of SQST-1 accumulation in different tissues and developmental stages. We also identified that the calpain protease clp-2 acts in a cell context-specific manner in SQST-1 degradation. clp-2 is required for degradation of SQST-1 in the hypodermis and neurons, but is dispensable in the body wall muscle and intestine. Our results indicate that autophagy genes are differentially employed in a tissue- and stage-specific manner during the development of multicellular organisms.

Abbreviations: ATG: autophagy related; CLP: calpain family; EPG: ectopic PGL granules; ER: endoplasmic reticulum; ESCRT: endosomal sorting complex required for transport; GFP: green fluorescent protein; LGG-1/LC3: LC3, GABARAP and GATE-16 family; MIT: microtubule interacting and transport; PGL: P granule abnormality protein; SQST-1: sequestosome-related; UPS: ubiquitin-proteasome system     

Trifunctional antibody ertumaxomab: Non-immunological effects on Her2 receptor activity and downstream signaling

Background: The trifunctional antibody ertumaxomab bivalently targets the human epidermal growth factor receptor 2 (Her2) on epithelial (tumor) cells and the T cell specific CD3 antigen, and its Fc region is selectively recognized by Fcγ type I/III receptor-positive immune cells. As a trifunctional immunoglobulin, ertumaxomab therefore not only targets Her2 on cancer cells, but also triggers immunological effector mechanisms mediated by T and accessory cells (e.g., macrophages, dendritic cells, natural killer cells). Whether molecular effects, however, might contribute to the cellular antitumor efficiency of ertumaxomab are largely unknown.

Methods: Potential molecular effects of ertumaxomab on Her2-overexpressing BT474 and SK-BR-3 breast cancer cells were evaluated. The dissociation constant K_d of ertumaxomab was calculated from titration curves that were recorded by flow cytometry. Treatment-induced changes in Her2 homodimerization were determined by flow cytometric fluorescence resonance energy transfer measurements on a cell-by-cell basis. Potential activation / deactivation of Her2, ERK1/2, AKT and STAT3 were analyzed by western blotting, Immunochemistry and immunofluorescent cell staining.

Results: The K_d of ertumaxomab for Her2-binding was determined at 265 nM and the ertumaxomab binding epitope was found to not overlap with that of the therapeutic anti-Her2 monoclonal antibodies trastuzumab and pertuzumab. Ertumaxomab caused an increase in Her2 phosphorylation at higher antibody concentrations, but changed neither the rate of Her2-homodimerization /-phosphorylation nor the activation state of key downstream signaling proteins analyzed.

Conclusions: The unique mode of action of ertumaxomab, which relies more on activation of immune-mediated mechanisms against tumor cells compared with currently available therapeutic antibodies for breast cancer treatment, suggests that modular or sequential treatment with the trifunctional bivalent antibody might complement the therapeutic activity of other anti-Her2/anti-ErbB receptor reagents.     

Methods for Monitoring Autophagy from Yeast to Human

The increasing interest in autophagy in a wide range of organisms, accompanied by an ever-growing influx of researchers into this field, necessitates a good understanding of the methodologies available to monitor this process. In this review we discuss current approaches that can be used to follow the overall process of autophagy, as well as individual steps, from yeast to human. The majority of the review considers methods that apply to macroautophagy; however, we also consider alternative types of degradation including chaperone-mediated autophagy and microautophagy. This information is meant to provide a resource for newcomers as well as a stimulus for experienced researchers who may be prompted to develop additional assays to examine autophagy-related pathways.     

Why Sick Cells Produce Tumors: The Protective Role of Autophagy

Cells exploit autophagy for survival to metabolic stress in vitro as well as in tumors where it localizes to regions of metabolic stress suggesting its role as a survival pathway. Consistent with this survival function, deficiency in autophagy impairs cell survival, but also promotes tumor growth, creating a paradox that the loss of a survival pathway leads to tumorigenesis. There is evidence that autophagy is a homeostatic process functioning to limit the accumulation of poly-ubiquitinated proteins and mutant protein aggregates associated with neuronal degeneration. Interestingly, we found that deficiency in autophagy caused by monoallelic loss of beclin1 or deletion of atg5 leads to accelerated DNA damage and chromosomal instability demonstrating a mutator phenotype. These cells also exhibit enhanced chromosomal gains or losses suggesting that autophagy functions as a tumor suppressor by limiting chromosomal instability. Thus the impairment of survival to metabolic stress due to deficiency in autophagy may be compensated by an enhanced mutation rate thereby promoting tumorigenesis. The protective role of autophagy may be exploited in developing novel autophagy modulators as rational chemotherapeutic as well as chemopreventive agents.

Addendum to:

Autophagy Supresses Tumor Progression by Limiting Chromosomal Instability

R. Mathew, S. Kongara, B. Beaudoin, C.M. Karp, K. Bray, K. Degenhardt, G. Chen, S. Jin and E. White

Genes Dev 2007; 21:1367-81     

Dissecting the localization and function of Atg18, Atg21 and Ygr223c

Atg18p and Atg21p are two highly homologous yeast autophagy proteins. Atg18p functions in both autophagy and the selective Cvt-pathway, while the function of Atg21p is restricted to the Cvt-pathway. The yeast genome encodes with Ygr223cp (Hsv2p) a third member of this protein family. So far no function has been assigned to Ygr223cp. By colocalization with the endosomal marker Snf7-RFP and an RFP-tagged FYVE domain, we here identify the localization of a pool of Atg18p, Atg21p and Ygr223cp at endosomes. Endosomal recruitment of all three proteins depends on PtdIns3P generated by the Vps34-complex II containing Vps38p, but not on the function of the Vps34-complex I. Since only the Vps34-complex I is essential for autophagy, we expect that at endosomes Atg18p, Atg21p and Ygr223cp have a function distinct from autophagy. Some Vps Class D mutants involved in Golgi-to-endosome transport are required for the endosomal recruitment of GFP-Atg18p, -Atg21p and –Ygr223cp. These include the Qa-SNARE Pep12p, its SM protein Vps45p, the Rab GTPase Vps21p and the Rab effector Vac1p. Deletion of ATG18, ATG21 and YGR223c, alone or simultaneously has no obvious function on the MVB-pathway and CPY-sorting. However, overexpression of ATG21 leads to CPY secretion. We further show, to our knowledge for the first time that Ygr223cp affects an autophagic process, namely micronucleophagy.     

Role of Wdr45b in maintaining neural autophagy and cognitive function

ABSTRACT

Macroautophagy/autophagy functions as a quality control mechanism by degrading misfolded proteins and damaged organelles and plays an essential role in maintaining neural homeostasis. The phosphoinositide phosphatidylinositol-3-phosphate (PtdIns3P) effector Atg18 is essential for autophagosome formation in yeast. Mammalian cells contain four Atg18 homologs, belonging to two subclasses, WIPI1 (WD repeat domain, phosphoinositide interacting 1), WIPI2 and WDR45B/WIPI3 (WD repeat domain 45B), WDR45/WIPI4. The role of Wdr45b in autophagy and in neural homeostasis, however, remains unknown. Recent human genetic studies have revealed a potential causative role of WDR45B in intellectual disability. Here we demonstrated that mice deficient in Wdr45b exhibit motor deficits and learning and memory defects. Histological analysis reveals that wdr45b knockout (KO) mice exhibit a large number of swollen axons and show cerebellar atrophy. SQSTM1- and ubiquitin-positive aggregates, which are autophagy substrates, accumulate in various brain regions in wdr45b KO mice. Double KO mice, wdr45b and wdr45, die within one day after birth and exhibit more severe autophagy defects than either of the single KO mice, suggesting that these two genes act cooperatively in autophagy. Our studies demonstrated that WDR45B is critical for neural homeostasis in mice. The wdr45b KO mice provide a model to study the pathogenesis of intellectual disability.

Abbreviations: ACSF: artificial cerebrospinal fluid; AMC: aminomethylcoumarin; BPAN: beta-propeller protein-associated neurodegeneration; CALB1: calbindin 1; CNS: central nervous system; DCN: deep cerebellar nuclei; fEPSP: field excitatory postsynaptic potential; IC: internal capsule; ID: intellectual disability; ISH: in situ hybridization; KO: knockout; LTP: long-term potentiation; MBP: myelin basic protein; MGP: medial globus pallidus; PtdIns3P: phosphoinositide phosphatidylinositol-3-phosphate; WDR45B: WD repeat domain 45B; WIPI1: WD repeat domain, phosphoinositide interacting 1; WT: wild type.