Considering　the　natural　reserves,　distribution　and　cost　of　sodium　resources,　sodium-ion　batteries　(SIBs)　have　been　regarded　as　a　potential　alternative　to　lithium-ion　batteries.　However,　it　remains　challenging　to　develop　the　excellent　electrode　materials　for　SIBs　owing　to　larger　Na　ionic　radius.　Herein,　multicomponent　Fe3O4/Fe1xS@C@MoS2@C　hybrid　has　been　designed　by　using　bone-like　Fe3O4@C　particles　and　carbon-coated　MoS2　nanosheets　as　the　core　and　shell,　respectively,　followed　by　sulfurization.　On　one　hand,　several　high-capacity　active　materials　are　well　organized　together,　which　can　fully　exert　the　synergies　among　them.　Meanwhile,　ultrathin　MoS2　nanosheets　with　expanded　interlayer　spacing　of　0.80　nm　are　confined　between　two　carbon　layers,　resulting　in　the　high　conductivity　and　good　structural　stability　of　the　whole　electrode.　Consequently,　the　prepared　Fe3O4/Fe1-xS@C@MoS2@C　anode　for　SIBs　exhibits　a　large　reversible　capacity　of　589.8　mA　h/g　at　100　mA/　g　after　200　cycles.　Even　at　a　higher　current　density　of　2　A/g,　it　still　keeps　a　high　specific　capacity　of　503.7　mA　h/　g.　The　theoretical　calculations　further　show　that　the　surface　of　Fe1-xS　is　more　advantageous　for　Na+　adsorption　in　comparison　to　that　of　Fe3O4,　due　to　the　stronger　charge　transfer　between　Na　and　neighboring　S　atoms,　which　greatly　boosts　the　sodium　storage　capability　of　Fe3O4/Fe1-xS@C@MoS2@C.