Perfect duet: Dual recombinases improve genetic resolution

Abstract As a powerful genetic tool, site‐specific recombinases (SSRs) have been widely used in genomic manipulation to elucidate cell fate plasticity in vivo, advancing research in stem cell and regeneration medicine. However, the low resolution of conventional single‐recombinase‐mediated lineage tracing strategies, which rely heavily on the specificity of one marker gene, has led to controversial conclusions in many scientific questions. Therefore, different SSRs systems are combined to improve the accuracy of lineage tracing. Here we review the recent advances in dual‐recombinase‐mediated genetic approaches, including the development of novel genetic recombination technologies and their applications in cell differentiation, proliferation, and genetic manipulation. In comparison with the single‐recombinase system, we also discuss the advantages of dual‐genetic strategies in solving scientific issues as well as their technical limitations.


| INTRODUCTION
Lineage tracing is the identification of all descendants of the marked founder cells, which provides information about the progeny status. 1 Typically, by performing immunofluorescence staining or in situ hybridization, the spatial distribution, proliferation and differentiation properties of offspring cells are presented. As a powerful tool in stem cell research, lineage tracing promotes our understanding of progenitor cell fate determination in embryonic development, tissue maintenance of homeostasis, tissue repair and regeneration in disease. 2,3 The crucial point, however, is how to accurately target the interested cells without unintended labelling, which is largely dependent on the capacity of genetic tools mediated by site-specific recombinases (SSRs).
Cre-loxP is one of the most widely used recombinase systems in lineage tracing. Cre recombinase is a 38KD protein originated from P1 bacteriophage, catalysing the recombination between two 34 bp sequences, loxP. 4 In the system, Cre targets the loxP sites specifically and excises the flanked elements (e.g., stop cassette) between two loxP in the same direction, unlocking the expression of the reporter behind the loxP; similarly, Dre-rox, 5 Flp-frt, 6 Nigri-nox, 7 VCre-VloxP and so on. 8 Due to the non-reversible and heritable recombination, all descendant cells express the reporter gene no matter what kind of subsequent cell fate transition events, transdifferentiation or proliferation. 9 In addition, in order to achieve temporal control, the ligandbinding domain of human oestrogen receptor (ER) is fused to Cre. 10 The compound CreER combines the heat shock protein 90 (HSP90) to keep inactivate in the cytoplasm. After Tamoxifen (Tam) treatment, CreER dissociates from HSP90 and translocates into the nucleus to work on the loxP sites. Thus, the inducible CreER can be extensively used to explore cell fate in a specific time window.
With a reporter line, Cre expression controlled by a cell-specific promoter allows selective labelling of the cell population of interest.
In this scenario, one tends to ideally consider that the reporter is exclusively expressed in a specific cell type. However, unanticipated activation of the reporter in other cell lineages, referred to as 'ectopic' expression, usually produces contradictory conclusions. 11,12 Actually, it is hard for a marker gene to be highly specific to one cell population.
On the other hand, a single marker is unable to identify one cell type and its sub-populations. 12,13 As a consequence, additional iterations of conventional single-recombinase methods are considerably needed to realize more precise lineage tracing. 14 By combining distinct and orthogonal recombinases, dual-recombinase-mediated genetic approaches have been developed to precisely label cell subtypes, capture transient gene activation, and perform genetic manipulation, among others. In this review, we discuss the working principles of dual-recombinase-mediated genetic approaches in exploring cell fate plasticity, and how to orchestrate different recombinases to resolve controversial issues with higher resolution than the singlerecombinase system.

| DUAL-RECOMBINASE-MEDIATED LINEAGE TRACING VIA OR-LOGIC
The conventional lineage-tracing tool greatly relies on the specificity of the marker gene, but the expression pattern of the gene might not be well documented, take Cre-loxP for example, there may be stochastic and unexpected Cre activation in the germline or during early development. 15 Furthermore, possibly the assumed 'specific' promoter is not specific because a single marker is not sufficient to define one cell type. 13,16 Nowadays, more precise expression maps of genes can be illuminated with the help of single-cell RNA sequencing (scRNA-seq). Meanwhile, new cell markers are expected to be identified. But the key point is how imperfectly 'specific' cell markers can be utilized to precisely trace cell fate in certain scientific issues. For unbiased lineage tracing, researchers introduced Dre-rox into the Cre-loxP system. 14 The OR-logic implies targeting the cell subpopulation negative for gene A of the other subpopulation when both subpopulations express the common gene A, which is especially helpful when there are no known markers for a subpopulation. Here we categorize the applications of the dualrecombinase system in solving some controversial questions by more precise fate maps.

| Precise fate-mapping of cardiac myocytes and nonmyocytes
The existence of endogenous cardiac stem cells (CSCs) in the adult heart is fascinating to cardiomyocyte regeneration after injury.
However, imprecise genetic tools have made the existence of CSCs contentious. c-Kit + cells were reported as CSCs and contributed to myocyte renewal after cardiac damage, 17 whereas other studies argued that c-Kit + cells harbour minimally myogenic potential of differentiation. [18][19][20][21] Subsequent studies clarified that it is the unintended labelling of c-Kit + cardiomyocytes that leads to the misinterpretation of Kit-CreER lineage. 18 To overcome the technical hurdle of non-specific recombination, an interleaved reporter line was established, named DeaLT-IR (dual-recombinaseactivated lineage tracing with interleaved reporter) ( Figure 1B). 14 Combined with IR1, Tnni3-Dre first and specifically secures the Dre-rox recombination in cardiomyocytes, simultaneously precluding Cre-loxP-mediated unwanted labelling of cardiomyocytes. And Kit-CreER-mediated Cre-loxP recombination leads to ZsGreen expression in c-Kit + non-cardiomyocytes after Tam induction ( Figure 1A). Based on the OR-logic-mediated strategy, no ZsGreen + cardiomyocytes were detected after cardiac injury, disproving the CSC potential of c-Kit non-cardiomyocytes in mammalian adult hearts. In addition to c-Kit, there could be other putative CSCs markers, 22-25 even some unknown and undefined. Another research used three different IR lines and the nested reporter DeaLT-NR to distinctly label cardiomyocytes and non-myocytes simultaneously, and four lineage tracing strategies independently revealed that there is no nonmyocyte-to-myocyte conversion in the adult heart. 26 2.2 | Tracing the Sox9 + biliary epithelial cell fate transition SOX9 has been reported to be expressed in biliary epithelial cells as well as a subset of periportal hepatocytes. 27 Hence, to reveal whether SOX9 + BECs transdifferentiate into hepatocytes in injury, new genetic tools should be developed to unambiguously label BECs and hepatocytes. The aforementioned DeaLT-IR1 permits sequential recombination, whereas DeaLT-NR allows simultaneous expression of CreER and DreER, still the Dre-rox system rigorously controls Cre-loxP recombination. 14 According to the OR-logic, Alb-DreER;Sox9-CreER;NR1 mice were generated, in which Cre was activated in both Sox9 + BECs and Sox9 + periportal hepatocytes upon Tam injection, while Dre-rox recombination only occurs in Alb + periportal hepatocytes. 14 As a result, SOX9 + Alb À BECs were tagged as ZsGreen + , while under Alb activation, Dre removes ZsGreen and the stop cassette, unlocking the expression of tdTomato specifically in SOX9 + Alb + hepatocytes ( Figure 1C,D). In vivo genetic evidence indicated that SOX9 + BECs do not give rise to de novo hepatocytes in homeostasis or injury.

| Lineage transdifferentiation between acinar cells and ductal cells
In the research of cell fate conversion among exocrine cells, previous studies have been contradictory about the contribution of ductal cells to acinar cells in adults, [28][29][30] as is the case with acinar-to-ductal metaplasia. 31,32 Based on a sequential recombination system, Tnni3-Dre; CK19-CreER;IR1 mice were generated to label ductal cells and acinar cells with different fluorescent proteins. 33 Given that CK19 is expressed in the majority of ductal cells and few acinar cells, constitutive Dre-mediated Dre-rox recombination preferentially and specifically occurs in Tnni3 + acinar cells, preventing the 'ectopic' labelling by CK19-CreER in acinar cells. In this way, the two types of cells can be labelled with distinct genetic markers simultaneously ( Figure 1E, F).
After that, acinar-to-ductal conversion was proved in the pathologic models of pancreatic ductal ligation and pancreatitis. The ductal-toacinar transition has also been found upon extreme acinar cell loss.

| ORTHOGONAL RECOMBINASES DECIPHER CELL FATE VIA AND-LOGIC
A specific cell population tends to be defined by more than one maker sometimes. 13 AND-logic strategies, which take the intersection of dif-

| Tracing bronchioalveolar stem cells in lung regeneration
To elucidate the role of bronchioalveolar stem cells (BASCs), a potential source of lung regeneration, [34][35][36] Figure 2B). In addition, club cells, AT2 cells, and BASCs can be distinctly labelled by three fluorescence simultaneously when Sftpc-DreER and Scgb1a1-CreER cross with the reporter line R26-TLR, achieving a synergetic effect greater than the sum of its parts ( Figure 2C). 38 Independently, based on Cre-loxP and Dox-controlled TetO-tTA system, another study generated BASC v-race mice, which utilized split-tTA mediated lineage tracing to label SPC + CCSP +

F I G U R E 1 Mechanisms and examples of OR-logic actualization. (A,B)
Kit-CreER is active in both non-CMs and CMs. To block Kit-CreER labelling in CMs, constitutive Tnni3-Dre induces Dre-rox recombination and removes the loxP site for Cre-recombination. (C,D) The working principle of the nested reporter (NR1) is that the inducible Dre-mediated recombination removes the Cre-induced ZsGreen expression, which allows the precise labelling of BECs without targeting any hepatocytes. (E,F) IR1 is used to precisely label pancreatic ductal cells without contaminating acinar cells.
BASCs and their derivatives in several pulmonary disease models. 39 The study demonstrated the stem cell properties of BASCs in terms of their ability to differentiate across multiple lineages in response to diverse damage.

| Generation of de novo smooth muscle cells for artery repair
Rapid vascular repair and regeneration are indispensable for maintaining arterial function after injury. The scRNA-seq provides plenty of detailed information about the heterogeneity of Sca1 + cell subpopulations and putative Sca1 + vascular stem cells. 40 Based on binary recombinases, intersectional genetics strategies were developed to track two subsets of Sca1 + cells. By crossing Pdgfra-DreER, Sca1-C-reER with the reporter line R26-RSR-LSL-tdTomato, PDGFRa + Sca1 + could be labelled as tdTomato positive only after both Dre-rox and Cre-loxP recombination upon Tam injection ( Figure 2D). 40 Nevertheless, compared with single-recombinase-mediate lineage tracing (Sca1-CreER;R26-tdTomato), the efficiency of the dual-recombinase strategy is lower because of the inducible Cre and Dre. Moreover, investigators employed a sequential genetic approach, Sca1-CreER; Pdgfrb-LSL-Dre;R26-RSR-tdTomato, in which Cre activation leads to Dre-rox recombination, securing tdTomato expression in PDGFRb + Sca1 + cells ( Figure 2E). Fate-mapping results suggest that PDGFRa + Sca1 + cells, but not PDGFRb + Sca1 + , in the adventitial layer of artery walls have been shown to differentiate into smooth muscle cells and migrate to the media layer after severe arterial injury ( Figure 2F).

| GENETIC PROLIFERATION TRACING BY DUAL RECOMBINASES
Cell proliferation is a typical manifestation of cell fate plasticity.
Nucleotide analog incorporation (EdU or BrdU) is a conventional practice in the field. However, accompanying negative side effects including antiproliferation and cell toxicity were reported. 41,42 Additionally, proliferation markers staining is also extensively used, for instance, cell cycle marker Ki67 (Mki67), cytokinesis marker Aurora kinase B (AuroraB or AURKB), phosphorylated histone H3 (PH3) and proliferating cell nuclear antigen . [43][44][45] Given that marker staining only reflects snapshots of cell proliferation, rather than continuous traces over a time window, still, signal interference is generated from other prolifer- administration is toxic to mice. Due to the limitations of current methods, a new genetic tool integrating Dre and Cre recombinases has been designed, ProTracer (Proliferation Tracer), which can noninvasively and seamlessly monitor in vivo cell proliferation. 48 Here, we review the adaptation of ProTracer to address academic controversies as well as its strengths and limitations.

| Monitoring zonal hepatocyte proliferation in physiology and pathology
Self-renewal of persisting hepatocytes is vital for maintaining the hepatocyte pool. 49 54 Thus, to visualize cytokinesis, clonal analysis by sparse labelling has been employed in the ProTracer system. 48 Compared to the conventional Ki67-CreER;R26-tdT strategy, the dual-recombinase-mediated ProTracer has the following advantages: continuous temporal recording of cell repopulation events, tissue specificity accompanied by a higher resolution ratio, reduced dependence on Tam and thus less cell toxicity, permitting long-term noninvasive monitoring of cell proliferation in vivo. It is worth mentioning that in the ProTracer system, not only DreER but also CrexER can respond to Tam induction. However, due to the transient nature of Ki67 expression, the likelihood that both Ki67 expression and Tam induction occur simultaneously in the interested tissue is quite small, and thus the effect is negligible. Besides, activation of the ProTracer system is time-consuming and, as detailed in the study, it takes several weeks to achieve a stable detection state in liver homeostasis. Moreover, it is inexplicable to figure out regional repopulation features in highly proliferative tissues. Conversely, ProTracer is especially adaptive in rarely proliferative cell lineages, for example, cardiomyocytes. 48 Thus, to illustrate the utility of the technique, we will discuss the application of ProTracer to cardiomyocyte proliferation in different phases in the following subsections.

| Tracking cell proliferation at multiple stages in the heart
Nowadays, a broad consensus has been reached that new cardiomyocytes are generated from self-proliferation. 55 To investigate cardiac regeneration in adult heart, the cardiomyocyte-tropistic AAV9-Dre primed ProTracer system was constructed, in which Dre-rox recombination switches cell-cycle marker Ki67-or Ccna2-driven CrexER to Ki67-Cre or Ccna2-Cre, respectively, thereafter, permanently labels Ki67 + or Ccna2 + cells by the GFP reporter. 56 To avoid regionpreferential viral infection, Tnnt2-DreER-triggered cardiomyocytespecific ProTracer was also generated ( Figure 3B). By exploiting multiple strategies, the regional distribution pattern of cycling cardiomyocytes in homeostasis and injury was revealed in the adult heart ( Figure 3C). Moreover, ProTracer has been adapted to reveal cardiomyocyte proliferation patterns in the developing mammalian heart.
Utilizing CAG-Dre primed ProTracer (R26-DreER;Ki67-CrexER; Tnnt2-mTnG) to seamlessly label Ki67 + cardiomyocyte cells, a rapid cell-cycle withdrawal in cardiomyocytes from birth to adolescence was proved, 57 disproving the previous conclusion that cell burst proliferation occurs during preadolescence. 58 Although the ProTracer system permits cycling cardiomyocyte labelling, it is unable to illustrate the progenitors of those proliferative cardiomyocytes. Additionally, as noted above, Ki67 or Ccna2 marked cell proliferation scarcely distinguishes polyploidization and cytokinesis events. However, the MADM system visualizes cell division by labelling two daughter cells as red and green separately, even though the efficiency of interchromosome recombination needs to be improved. 46 Possibly in combination with the MADM system, the Pro-Tracer system could be advanced in the future to record cell proliferation more precisely by continuously capturing authentic in vivo cell division events.

| SEAMLESSLY RECORDING GENE ACTIVATION DURING CELL TRANS-DIFFERENTIATION
In vivo gene expression patterns are complex and changeable in diverse biological processes. 59 As for recording the expression of a particular gene, a single inducible recombinase system is unable to constantly operate without drug induction, and it is difficult to identify the gene over a time window through a constitutive singlerecombinase strategy. Meanwhile, tissue specificity is hard to accommodate. However, the proposed dual-recombinase system circumvents the problems above. Similar in theory to ProTracer, it converts an inducible recombinase to a constitutive one, hence permitting continuous recording of gene activation in specific cell types, especially for the short-term or transiently expressing genes ( Figure 3D). Not only for proliferation as described above, but here we also discuss the application of the dual-recombinase system to seamlessly capture gene activation during cell transdifferentiation.

| Detection of capillary to coronary artery formation in the adult heart
As a marker of angiogenesis, Apelin (APLN) is highly expressed in sprouting capillaries but it is challenging to label APLN + capillaries in the adult heart as its decreased expression. 60 Besides, the indistinguishable labels of all capillaries have low signal-to-noise ratios. Turning to the dual-recombinase system, under the initial Tam treatment, the inducible Apln-CrexER is converted to the constitutive Apln-Cre by Cdh5-DreER, thus incessantly records the activation of Apln in CDH5 + capillary endothelial cells (ECs). Then, the GFP could be activated if APLN + ECs contribute to artery formation driven by Cx40 expression. By employing this strategy, investigators demonstrated that capillary ECs contribute to arteries in the adult heart after myocardial infarction. 61

| Capturing EMT activity during tumour metastasis
It is widely acknowledged that epithelial-to-mesenchymal transition (EMT) occurs in diverse processes including embryonic development and pathological conditions such as tumorigenesis, invasion and metastasis. 62,63 Given that EMT is transient and reversible, 64 the conventional single-recombinase lineage tracing strategy may not accurately record the EMT programme. That means using EMT-genedriven CreER with a reporter line or by immunofluorescent staining for mesenchymal markers in lineage-tagged cancer cells. 65 To precisely visualize in vivo EMT in the metastatic cascade, researchers developed a novel genetic approach based on Cre and Dre dual recombinases to seamlessly record EMT gene activation. In the system, MMTV-PyMT induces breast adenocarcinoma tumorigenesis spontaneously. 66 Figure 3E). The EMTracer model is temporal-controlled, tissue-specific and with a strong resolution, proving that N-cadherin is functionally required during breast-to-lung tumour metastasis, instead of Vimentin ( Figure 3F). 67,68 Cre-and Flp-coupled dual-recombinase systems were also established to detect EMT in pancreatic carcinoma. 69 Figure 3G). 69 However, in KPF; aSMA-Cre;R26 Dual mice, either aSMA + myofibroblasts or aSMA + EMT cancer cells could be marked as tdTomato ( Figure 3H), thus requiring epithelial cancer cell markers to distinguish them. In addition, it is difficult to explain whether EMT in embryonic development may interfere with the results due to constitutive Cre being driven by aSMA. However, another mouse model of PDAC, FSF-Kras G12D/+ ;Pdx1-Flp;FSF-R26 CAG-CreERT2 , is capable of temporal control. As the readout of Flpfrt recombination is CreER, the inducible Cre can be used for genetic manipulation in the Pdx1-Flp lineage, including gene knockout and cell depletion in a time window. 70

| Recording mesenchymal gene activation in cardiac fibrosis
To testify whether myofibroblasts are derived from endothelial to mesenchymal transition (EndoMT) in adult cardiac fibrosis, investigators crossed Cdh5-CreER, aSMA-LSL-Dre and aforementioned NR1, generating aSMA-EndoMTracer. 71 After Tam induction, Cre-loxP recombination yields ZsGreen + ECs and the aSMA-Dre allele. Transient aSMA activation enables the switch from ZsGreen to tdTomato via Dre-rox recombination, and the ECs could be irrevocably labelled as tdTomato + even if they subsequently transdifferentiate into mesenchymal cells. Together with the Zeb1-EndoMTracer, EndoMT was illuminated in embryonic heart valve formation, but not in adult cardiac fibrosis. Parallelly, Col1a2-CreER;aSMA-LSL-Dre;NR1 demonstrated that fibroblasts contribute to cardiac fibrosis. 71 However, a caveat of the above approach is the crosstalk of Cdh5-CreER with NR1, where Cre targets rox sites and unlocks the expression of tdTomato independent of aSMA activation. In order to circumvent the potential risks, strict control should be established under the same experimental conditions.

| IN VIVO GENE MANIPULATION BY THE DUAL-RECOMBINASE SYSTEMS
Tissue-specific conditional mutants have been extensively used to study gene function in vivo during development, homeostasis or pathological states. Typically, the vital element (e.g. exons) of the target gene is flanked by two unidirectional loxP, and the gene becomes non-functional after Cre site-specific recombination. 4 Compared with germline null mutations, tissue-specific gene deletion can circumvent embryo lethality occasionally; moreover, temporal control of conditional mutagenesis (e.g. by CreER) identifies gene functions at a particular time point. 72 However, neither the inducible nor the constitutive single-recombinase system is perfect for gene deletion, as the former is temporal but inefficient, and the latter is efficient but non-temporal. And both of them are limited by a single promoter. It is better to combine their merits and overcome their defects at the same time. Hence, a gene-manipulating dual-recombinase system was developed for high-resolution conditional mutagenesis. A novel dual-recombinase system involving Dre and inducible Cre has been developed to perform specific and efficient gene deletion in vivo in white adipose tissue (WAT), in which pan-adipocyte marker PLIN1 and brown adipocyte tissue-(BAT) specific marker UCP1 was used. 74 In the presence of Dre driven by Ucp1, the rox-flanked CreER was removed in Plin1-rox-CreER-rox (Plin1-dCreER) mice ( Figure 4A).

| Dual-genetic strategies for gene knockout
Since Cre was the readout in WAT in this intersectional genetic system, Plin1-dCreER;Ucp1-Dre;Pparg fl/fl mice were generated to knock out the gene Pparg in WAT specifically but not BAT. 74 Compared with traditional pan-adipocyte gene ablation, 75 this system enables more specific and efficient gene deletion. In addition to the NOT-logic, AND-logic strategy, Cdh5-Dre;Prox1-RSR-CreER;Mettl3 fl/fl mice were also generated to specifically delete the gene Mettl3 in CDH5 + PROX1 + lymphatic ECs (LECs) ( Figure 4B). As Prox1 is also expressed in other cell lineages, 76,77 using the conventional Prox1-CreER line to target LECs may confound the interpretation of gene functions, whereas the dual-genetic strategy improves the accuracy of gene knockout by enhanced tissue specificity.
Taken together, more than acting as a powerful lineage-tracing tool, the dual-recombinase systems also perform high-resolution genetic manipulation that is unattainable with the single-recombinase systems.

| Cellular function studies via the dualrecombinase systems
In order to obtain functional information at the cellular level, typically genes associated with cell death, pyroptosis, or apoptosis are endogenously expressed. For instance, GSDMD N-terminal (GSDMD-NT) could induce pyroptosis, 78,79 and P21 induces cell proliferation inhibition and senescence. 80,81 Besides, chemical-genetic cell ablation strategies such as the NTR-MTZ system in zebrafish, and the DT-DTR system in mammals also work efficiently under spatial and temporal control. 82 Since the non-specific labelling by a single marker may lead to misunderstanding, 84-86 researchers took advantage of Ins2-Dre; R26-iCre;IR1-DTR mice to distinguish beta cell and non-beta cell by labelling them as tdT-DTR + and ZsGreen + , respectively ( Figure 4C).
After DT administration, the vast majority of beta cells (>99%) were genetically cleared. The IR-DTR system captured a few ZsGreen + cells contributing to a subset of insulin + cells, meanwhile, indicating the sensitivity of the system. 87 Together, the combination of DT-DTR and the intersectional genetic manipulation approach further demonstrates the broad compatibility of the dual-recombinase system.

| CONCLUSION AND DISCUSSION
As mentioned above, the dual-recombinase system exhibits its potent faculty due to the improved spatiotemporal specificity, higher efficiency and resolution in numerous scientific issues that conventional single-recombinase systems cannot achieve. Not only does it avoid the risk of unnecessary labelling by single promoter-driven recombination, but also it is able to continuously monitor transient gene activation during cell proliferation and cell fate transitions. Furthermore, more specific in vivo genetic manipulation can be achieved due to the accurate targeting of different cell populations by the dualrecombinase approaches.
As a system depending on transgenic animals and SSRs, the dualrecombinase system inherits the challenges of SSRs in the way of faithfully reflecting endogenous molecular expression map, and probably exacerbates the issues due to its increased complexity. The recombination efficiency, tissue specificity, 88 93 which have much higher throughput at the single-cell level and allow data-driven rather than hypothesis-driven research compared to conventional lineage tracing. 94 However, these technologies require multiple large genetic modules, are not well-controlled in vivo, contain a certain amount of noise information, or have a low editing efficiency that impedes a clear interpretation of the data. 95 It could be very rewarding if we combine the dual-recombinase system with single-cell lineage tracing to control the expression of these above-mentioned machinery in vivo with both tissue and temporal resolution remained.
With the development of omic technologies like deep sequencing, spatial transcriptomics and mass spectrometry, genetic systems with SSRs can be enhanced with dual-recombinase systems. New marker genes of specific cell subtypes locked on by dual recombinases can be identified by deep sequencing. Proximal cell and molecule profiling by gLCCC/gTCCC 96 and proximity labelling 97 that utilizes synNotch and HRP modules can be tamed by dual recombinases and combined with spatial transcriptomics or proteomics to unveil in vivo and in situ cellcell interaction and the underlying molecular mechanisms. Moreover, live imaging with cell fate mapping allows for real-time and in situ inspection of cellular processes and can facilitate the use of photoactivatable recombinases for light-controlled recombination with tissue and temporal constraints. 98,99 Besides, the application of the dualrecombinase system in the fields of cell origin, proliferation and differentiation has provided conclusive evidence for cell fate plasticity until now, yet has barely penetrated the fields of cell senescence, apoptosis or cell death. Therefore, further iterations of this genetic approach are urgently needed to broaden its reach to interpret the entire life of cells and address more unsettled scientific questions in biological processes.
By integrating different SSRs, dual-recombinase-mediated lineage tracing and manipulation provide higher spatiotemporal resolution than single recombination strategies, while also having strong compatibility to cooperate with other technologies to expand its applications.

CONFLICT OF INTEREST STATEMENT
No conflict of interest.

DATA AVAILABILITY STATEMENT
Data sharing is not applicable to this article as no new data were created or analyzed in this study.