Huge　volume　expansion　and　inferior　electrical　conductivity　are　the　two　main　obstacles　to　limit　the　practical　applications　of　high-capacity　molybdenum　disulfide　(MoS2)　materials,　which　has　been　recognized　as　ideal　anode　materials　for　rechargeable　lithium-ion　batteries.　Herein,　an　interfacial　reinforcement　structure　design　is　proposed　by　conformally　growing　few-layered　MoS2　nanosheets　on　carbon　coated　ultralong　TiO2　nanotubes　(TiO2@C@MoS2)　to　stabilize　the　solid　electrolyte　interface　(SEI)　of　MoS2-based　electrode.　The　interlayer　carbon　coating　on　TiO2　nanotubes　effectively　improves　the　interfacial　contact　between　MoS2　nanosheets　and　TiO2　nanotubes　by　forming　Ti-O-C　and　C-S　chemical　bonds　between　TiO2/carbon　coating　and　MoS2/carbon　coating,　respectively,　avoiding　MoS2　nanosheets　detaching　from　TiO2　nanotubes.　Meanwhile,　the　carbon　coating　serves　as　a　buffering　cushion　to　alleviate　mechanical　strain　at　the　interface　of　MoS2　nanosheets　and　TiO2　nanotubes.　Besides,　it　enhances　the　adsorption　performance　of　Li　ions　on　the　surface　of　MoS2　and　at　the　interface　sites　between　MoS2　and　TiO2.　While　three-dimensional　rigid　TiO2　nanotubes　networks　work　as　mechanical　support　to　suppress　reaggregating　and　restacking　of　MoS2　nanosheets,　and　provide　fast　transportation　expressways　for　electrons/ions.　Thus,　the　TiO2@C@MoS2　electrode　exhibits　ultrafast　charge/discharge　capability,　a　high　reversible　capacity　of　1150　mAh　g(-1)　at　0.1　A　g(-1),　and　superior　cycling　performance　with　90%　capacity　retention　after　1500　cycles　at　1.0　A　g(-1).　This　interfacial　reinforcement　structure　design　provides　valuable　experience　to　benefit　rational　design　of　alloy/conversion-typed　materials　electrode　with　high-performance.