Isoprenoids constitute perhaps the most diverse of natural products serving as vital functions in all living being. All isoprenoids are constructed from one or both of two basic precursors, C5-dimethylallyl pyrophosphate (DMAPP) and C5-isopentenyl pyrophosphate (IPP). Here, geranyl pyrophosphate synthase (GPPs), belonging to trans-prenyltransferases forming all-trans prenyl diphosphates through trans double-bond addition, catalyzes the condensation of C5- DMAPP with C5-IPP to generate C10-Geranyl pyrophosphate (GPP), a precursor of monoterpenes which function as defensive agents, pollination attractants, and major floral scent compounds in plant. Intriguingly, distinct from other solved structures of trans-prenyltransferases, which are homodimers or homohexamer, Mentha x piperita GPPs is proven to be as a functional heterotetramer, composing of two large subunits (2L) and small subunits (2S). The large subunit has the conserved functional motif, DDXXD, and a high amino acid sequence identity with geranylgeranyl pyrophosphate synthase (GGPPs). Notably, the small subunit has neither the conserved motif nor the sequence identify with other trans-prenyltransferases. In addition, previous studies indicated that the small subunit involved in product formation and substrate specificity and interacted with the large subunit and other GGPPs. Moreover, spatial and temporal expressions of small subunit in plant revealed closely correlating with monoterpene emission in contrast to large subunit having constitutively expressed in all developmental and flowering stages. Thus, the distinct roles of small and large subunit in the regulation mechanism and quaternary structure formation of heterotetramer (2L2S) in vitro and vivo still remain elusive. Here, we use structural biological and biochemical approaches to elucidate the structural properties of Mentha x piperita GPPs. At first, to improve the poor yield of recombinant GPPs expressed in Escherichia coli, both large and small subunit carrying the thioredoxin fusion tag in front of their N-terminus can significantly increase approximately 10-fold protein yield. But, due to the bottleneck of further purification and isolation, coexpression of small subunit with His-tag in its C-terminus and large subunit is applied to high-level purity and functional heterotetrameric proteins. The first heterotetrameric (2L2S) Mentha x piperita GPPs structures, including apo-form and complex with DMAsPP, IPP, and Mg2+ ions, were determined to resolutions of 1.9 Å and 2.2 Å, respectively. Large subunit is composed of 12α-helices joined by connecting loops around a central cavity containing two DDXXD motif at the top for substrate binding; Small subunit is composed of 11α-helices to form the similar structure fold to trans-prenyltransferases. By comparing the large subunit of Mentha x piperita GPPs with the solved structure of Sinapis alba GGPPs, it reveals that they have not only high amino acid sequence identity (about 74%) but also very similar structure, especially in their catalytic sites. In addition, based on functional assay, Mentha x piperita GPPs can generate C10-GPP and C20-GGPP when the sufficient substrates and enough catalytic reaction time are provided. Therefore, we suggest that large subunit may exhibit a function of GGPPs. Intriguingly, small subunit with the enzymatic activity of GPPs is observed here in contrast to the previous studies which mention no detectable prenyltransferase activity. Thus, why small subunit, a kind of GPPs, must interact with large subunit, functional GGPPs? The mutagenesis and enzyme kinetic assay will used to elucidate these mystery questions.