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Review

Indolent T- and Natural Killer-Cell Lymphomas and Lymphoproliferative Diseases—Entities in Evolution

by
Chi Sing Ng
Department of Pathology, Caritas Medical Center, Shamshuipo, Kowloon, Hong Kong
Lymphatics 2025, 3(4), 41; https://doi.org/10.3390/lymphatics3040041
Submission received: 23 October 2025 / Revised: 10 November 2025 / Accepted: 27 November 2025 / Published: 29 November 2025
(This article belongs to the Special Issue Indolent Lymphomas and Lymphoreticular Proliferative Diseases)
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Abstract

Indolent lymphoproliferative diseases or disorders (LPDs) derived from T cells or Natural Killer (NK) cells may be neoplastic or non-neoplastic, which are often difficult to distinguish from each other and from their aggressive counterparts. The etiology and pathogenesis are mostly nebulous and may be related to infections or immune dysfunction. Indolent lymphomas differ from the high-grade aggressive counterparts by a prolonged clinical course of persistent or relapsing disease, histology, immunophenotype, and genetics. In recent decades, indolent lymphomas or LPD of T or NK cell derivation have been increasingly recognized, causing diagnostic and nosologic confusion. The issue is particularly challenging in the arena of indolent intestinal lymphomas and LPD, as evidenced by the myriad of names given to the indolent intestinal T- and NK-cell lymphomas and LPD. Confounding the picture are also reports of Epstein–Barr virus (EBV) positivity in various indolent non-intestinal LPD and, rarely, even in indolent intestinal T-cell lymphoma, which have been widely accepted to be typically EBV-negative. This review aims to curate current information and understanding of these diseases with the goal of resolving these issues. The recently described indolent T-lymphoblastic proliferation (iTLBP) and the re-classified indolent primary cutaneous CD4-positive small or medium T-cell LPDs and primary cutaneous acral CD8-positive T-cell LPDs also require greater awareness and recognition. It is important to diagnose these indolent entities in order to avoid over-treatment and unnecessary therapeutic intervention and to provide for accurate prognostic prediction and appropriate follow-up.

Graphical Abstract

1. Introduction

Most primary gastrointestinal (GI) NK- or T-cell lymphomas are aggressive high-grade lymphomas [1]. In the past three decades, there have been reports of indolent T- and NK-cell LPDs of the GI tract, designated by a plethora of names. The myriad names given to these entities reflect the enigma of their biology, behavior, and nosology. These are clonal proliferations and widely accepted to be EBV-negative [2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51]. This compares with their high-grade counterparts, which may be EBV+ (in extranodal NK/T-cell lymphoma of the GI tract-ENNKTL) [52] or EBV− (in monomorphic epitheliotropic intestinal T-cell lymphoma- MEITCL and enteropathy-associated T-cell lymphoma-EATCL) [53,54,55]. Interestingly, there are also rare reports of EBV positivity in indolent intestinal T-cell lymphoma (iITCL) [7,26,29] and EBV-positive indolent non-intestinal NK- or T-cell LPDs [56,57,58,59,60,61,62,63,64,65]. This observation subjects the widely accepted belief that indolent T-cell GI lymphomas (ilTCL) are EBV-negative to question. The reported molecular features of indolent GI LPD also differ from those of ENNKTL, MEITCL, and EATCL [2,3,4,7,19,22,25,26,27,28,31,32,49,50,52], despite some overlap in alterations of genes related to the JAK/STAT pathway. There are other recently recognized or re-categorized indolent T-cell LPDs, including indolent T-lymphblastic proliferation (iTLBP), primary cutaneous CD4+ small or medium T-cell LPD (PcutCD4+TLPD), and primary cutaneous acral CD8+ T-cell LPD (PcutacCD8+TLPD), that require greater attention [32,66,67,68,69,70,71,72,73]. This review summarizes the hitherto reported clinical, morphologic, and immunophenotypic features; the evolving genetic landscape; and the dubious possible role of EBV in these entities.

2. Indolent Intestinal Lymphoma and LPD

These have received attention in the past three decades. This review retrieved papers on these entities by searching Scopus and Google Scholar for the period 1990 to 2025 with the keywords “indolent, T-cell, NK-cell, lymphoma, lymphoproliferative disease, lymphomatoid gastropathy and enteropathy, intestinal, gastrointestinal, colon”. Fifty-six publications were retrieved. The major difficulty for inclusion is the lack of a numerical definition for the durati
n of indolence. “Indolence” linguistically means “laziness”, “sluggishness”, “languishment”, or “lethargia”. Medically, an indolent disease is slow-moving, often asymptomatic, and requires no treatment [32]. For the purpose of inclusion in this review, the empirical disease duration of “over one year” was adopted. Based on this empirical inclusion criterion and other keywords used in the search, three case reports/series were excluded because the disease durations were less than 1 year. Five review articles were also excluded because no additional cases of indolent lymphomas or LPD were described. As a result, 48 publications were included for review. A total of 85 cases of indolent intestinal T-cell lymphoma (iITCL) and 58 cases of indolent intestinal NK-cell LPD (iINKLPD) were identified and analyzed.

2.1. Indolent Intestinal T-Cell Lymphoma

This was first described by Carbonnel et al. in 1994 under the name of “extensive small intestinal lymphoma of low-grade malignancy associated with a new chromosomal translocation” [4]. The reported case manifested non-specific abdominal symptoms with insignificant intestinal endoscopic findings. The patient eventually developed acute small bowel obstruction, and the resected small bowel featured dilatation, thickened walls, and multiple 1–2 cm diameter serosal tumors associated with enlarged mesenteric lymph nodes. Small bowel histology revealed massive involvement that was limited to the mucosa by a diffuse infiltrate of small atypical lymphoid cells, associated with multiple non-caseating granulomas. The mesenteric lymph nodes and the liver portal tracts were involved with a similar atypical lymphoid infiltrate. Immunophenotypically, the lymphoid cells were T-cells expressing CD3, CD4, and betaF1, but negative for CD8. There was negligible Ki67 staining. A chromosomal translocation t(4;16)(q26;p13) involving the interleukin-2 (IL-2) gene was also detected.
This report was followed by many other similar reports under designations of “small intestinal, gut, GI tract, stomach, indolent T-cell, CD4−positive lymphoma, lymphoprolferative disease” in varying word combinations [4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32]. This great variability in the use of designations reflects uncertainty within the then academia about the nature of this entity. This review collected 85 cases of iITCL. There were 55 males and 30 females, with an age range of 14–80 years and a median age of 50 years. The reported cases had a wide geographic distribution from Europe, Asia, to Africa. As in the case reported in 1994 [4], all presented with non-specific abdominal symptoms, including bloating, pain, diarrhea, and weight loss. One was complicated by intestinal obstruction [4] and another by intestinal perforation [12]. Extraintestinal involvement or metastasis was reported in mesenteric lymph nodes [4,7,12,14,15,26,27,28,29,31,32], liver [4,7], peripheral blood [4,7,12,32], bone marrow [13,14,18,22,32], tonsil [14], lungs [4,7], skin [4,7,32], and epiglottis [32]. In two cases, inguinal lymph node involvement was reported [22], which was unusual, as metastasis to peripheral lymph nodes has been regarded to be very rare or absent in iITCL. The histology of the reported iITCL cases was similar to those described by Carbonnel [4].

2.1.1. Involved Sites and Gross Presentation

iITCL involves mostly the small intestine and the colon. However, other GI sites, including the stomach, esophagus, and oral cavity, may also be involved [5,6,8,10,12,13,14,16,18,22,23,24,32]. Multifocal involvement of the GI tract is common [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32], with gross presentations of polyps, folds, nodules, fissures, or ulcers [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32].

2.1.2. Histology

iITCL is characterized by non-destructive, partial involvement of the intestinal wall, often restricted to the lamina propria of the mucosa. A proportion of cases, however, may also show an involvement of the muscularis mucosae or submucosa. There is usually no epitheliotropism, and the surface and glandular epithelium are usually spared. In some cases, there are non-caseating granulomas or conspicuous eosinophils [2,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32]. The infiltrate is typically composed of atypical small to medium lymphoid cells with irregular dark nuclei and infrequent mitotic activity. There is no angiocentricity or angioinvasion (Figure 1) [2,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32].

2.1.3. Immunophenotype

The atypical lymphoid cells exhibit a T-cell phenotype and are positive for T-cell receptor (TCR, mostly beta and uncommonly gamma), CD3, CD2, CD4, CD5, CD7, and CD8. There are more CD4+ than CD8+ iITCLs. According to the pattern of expression of CD4 and CD8, iITCL can be categorized as CD4+/CD8−, CD4−/CD8+, CD4+/CD8+ and CD4−/CD8− [2,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32]. This immunophenotypic categorization appears to correlate well with non-neoplastic T cells. CD8+ iITCL more frequently express TIA1 (but not granzyme B or perforin [13,21,22,24,25,26,27,28,29]. These different immunophenotypes of iITCL show different genetic features (see Section 2.1.4) and may have a bearing on pathogenetic mechanisms. Though there had been reports of CD4+ iITCL running higher risks of disease progression [7,12,18,19,22], this association is no longer documented in the fifth edition of the WHO Classification [2]. The sentence “Cases expressing CD4 rather than CD8 appear to be at higher risk for progression, although data are limited” appeared in the 2017 edition of the WHO Classification [33]. The references cited were works of Carbonnel et al. [7] and Margolskee et al. [12]. Despite additional reported CD4+ iITCL cases that progressed to higher-grade disease since 2017 [18,19,22], the paraphrase from the 2017 WHO Classification was no longer included in the fifth edition [2]. It is speculated that the conclusion was not made due to the paucity of reported CD4+ iITCL cases with disease progression. Ki67 proliferation index is low and mostly <10%. Ki67 index is apparently not correlated with the risk of disease progression, since it was low in two cases [12,22] and not reported in three cases [7,18,19].

2.1.4. Genetic Alterations

(a)
TCR rearrangement
Clonal TCR rearrangement is present in all iITCL, more commonly TCR beta and less commonly TCR gamma [1,2,4,5,6,7,8,9,10,11,12,13,14,15,16,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32].
(b)
JAK/STAT and NF-ĸB-pathway-related genes
There are more frequent in CD4+/CD8−, CD4+/CD8+, and CD4−/CD8− iITCL [19,22,25,26,27,28,31]. Using Next-Generation Sequencing (NGS), alterations in STAT3 and JAK2, resulting in JAK2::STAT3 fusion, have been demonstrated [19,22,25,26,27,28]. Other genes with demonstrated alterations include STAT3 SH2 mutation, STAT5 alteration, and SOCS1 deletion. Mutations in epigenetic modifier genes DNMT3A, EZH2, KMT2D, TET2, and TNFAIP3 that contribute to JAK/STAT pathway activation are also identified, more commonly in CD4+/CD8− and CD4−/CD8− iITCL [2,27,28,31]. Activation of the NF-KB pathway through histone modification of KMT2D and methylation of TET2 may also contribute to pathogenesis.
(c)
IL2 gene
IL2 gene alterations occur more commonly in CD8+ than CD4+ cases [2,22,28,31]. Implication of the IL2 gene in iITCL was first demonstrated by traditional G-banding cytogenetic study [4], and later also by NGS. NGS uncovered IL2::RHOH (Ras homolog family member H) fusion due to inversion of chromosome 4 and IL2:TNIP3 (TNFAIP3 interacting protein 3) fusion [22,28]. RHOH deficiency has been shown to be associated with T helper 17 cell polarization and T-cell defects [74,75]. In CD4−/CD8+ iITCL, deletion of 3′ untranslated regions of IL2 and mutation of MCM5 (minichromosomal maintenance complex 5) have been demonstrated [22].
(d)
Other genetic alterations
Alterations in DIS3, MAPK1, TP53, POLE, SMAD4, SFB1, and CDKN2A have also been reported in some cases of CD4+ iITCL [22].
The number of studies and reported cases, however, is hitherto small, and it is too early for a definitive conclusion on distinctive pathogenetic and genetic differences among the different immunophenotypic categories of iITCL to be made. Furthermore, the number of genes and gene panels studied so far is limited, and the technological methods used vary from study to study. With future evolution in molecular methodology, the discovery of more genetic alterations in these indolent T-cell lymphomas may be made. It remains to be seen whether better correlation of immunophenotype, genetics, pathogenesis, and prognosis in iITCL can be achieved in the future.

2.1.5. Etiology and Role of EBV

The etiology of iITCL has remained nebulous. It has been etiologically associated with persistent antigenic stimulation [22], Crohn’s disease [10,76], autoimmune enteropathy [14], and coeliac disease [7]. None of these postulations, however, has been substantiated by further evidence. It is widely accepted that iITCL is not associated with EBV and is typically EBV-negative. Among the eighty-five cases identified by this review, however, only twenty-two cases had been tested for EBV (22/85, 26%). Of those tested for EBV, nineteen were EBV-negative (19/22, 86%) and three were EBV-positive (3/22,13%) [7,26,29]. It is notable that the status of EBV infection was unknown in the remaining majority of reported iITCL cases (63/85,74%). Therefore, the common belief that iITCL is EBV-negative was founded on a small percentage of EBV-tested cases. The methodology of EBV detection was not mentioned in a significant number of reports, but in situ hybridization for EBV-encoded small RNA (EBER) in tissue sections was the most frequently used methodology, including the three EBV-positive cases [7,26,29]. Though EBER is regarded as the preferred method for detecting latent EBV infection in tissue sections [77,78,79,80], there are alternative methods of EBV detection [56,57,59,77,78]. By using these alternative methods, it may be possible that the reported EBV-negative cases may be reclassified as EBV-positive. Testing the remaining EBV-unknown cases may also skew the hitherto reported EBV status in iITCL. Since there were documented cases of EBV+ iITCL (three cases, 13%) [7,26,29], with 1 CD8+ case showing a high Ki67 index of 90% [29], the role of EBV in iITCL remains to be explored. The possibility of two groups of iITCL, namely EBV- and EBV+, therefore, remains to be further studied. These two possible groups may be different in immunophenotype, genetics, and clinical behavior. It is well known that EBV+ NK-/T-cell lymphomas and leukemias carry a grave prognosis and require aggressive treatment [55]; the implication of EBV-positivity in iITCL needs to be further studied.

2.1.6. Neoplastic Nature of iITCL

The true biological nature of indolent intestinal T-cell proliferations had been enigmatic, as reflected by the plethora of names ranging from “proliferative disorders, diseases to lymphomas” given to these entities in the literature in the past three decades [4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32]. The body of cumulative information and evidence hitherto on this entity is in favor of its neoplastic nature, as follows:
  • Ability to disseminate. There have been multiple reports of dissemination to various non-intestinal distant sites, including mesenteric lymph nodes, liver, lungs, skin, tonsils, epiglottis, peripheral blood, and bone marrow, as described in Section 2.1 above [4,7,12,13,14,15,18,22,26,27,28,29,31]. More importantly, dissemination to inguinal lymph nodes had also been reported in 2020 in two cases [22]. This is in striking contrast to the former belief that lymph nodes spread from iITCL should be limited within the abdomen.
  • Disease Progression. Progression or transformation to higher-grade lymphoma was documented in five of eighty-five cases (6%) [19,20,22]. Three cases transformed to overt T-cell lymphoma [19,20], with one demonstrated to share the same STAT3::JAK2 fusion as the pre-existing iITCL.
  • Frequent Genetic Mutations. Alterations in TCR genes, genes of the JAK/STAT signaling pathway, and epigenetic modifier genes that contribute to JAK/STAT activation, IL2 gene, and DIS3, MAPK1, TP53, POLE, SMAD4, SFB1, and CDKN2A gene alterations in many cases, as discussed in Section 2.1.3 [2,4,16,18,19,20,21,22,23,24,25,26,27,28,29,31].
In the fifth edition of the WHO Classification of Hematolymphoid Tumors [1,2], the neoplastic nature of iITCL is recognized due to the significant morbidities related to the disease and its ability to disseminate. This entity is redesignated to “Indolent T-cell Lymphoma of the Gastrointestinal Tract” [33]. The reclassification of these entities as lymphomas represents formal recognition of their neoplastic biologic nature. iITCL thus requires greater awareness, accurate diagnosis, and proper management.

2.1.7. Treatment

Among the eighty-five reported cases, twenty-three cases did not receive any specific treatment, one was treated with surgery, nineteen with chemotherapy, five with steroids, eight with a gluten-free diet, one with mogamulizumab, and whether treatment was instituted was not mentioned for the remaining twenty-eight patients. Though the initial response was favorable in a handful of treated cases, the clinical course of iITCL was indolent with persistent or relapsing disease, irrespective of the treatment modality or whether treatment was instituted or not [4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32].

2.2. Indolent Intestinal NK-Cell Lymphoproliferative Disease (iINKLPD)

iINKLPD is a more recently recognized entity than iITCL [3,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51], and was initially designated lymphomatoid gastropathy (in the stomach) and NK-cell enteropathy (in the remaining intestine tract). It behaves in an indolent fashion as a persistent or relapsing disease over long durations. The common presentations include vague abdominal symptoms or may be asymptomatic, only to be discovered incidentally on endoscopy. This review uncovered fifty-eight cases of iINKLPD from eighteen case reports or case series. There were twenty-three males, thirty-three females, and two cases with unidentified sex. The age ranged from 14 to 76 years (median 52 years). One case also showed concomitant involvement of the glans penis [48], while all the remaining fifty-five cases showed only involvement of the GI tract [34,35,36,37,38,39,40,41,42,43,44,45,46,47,49,50].

2.2.1. Sites of Involvement and Gross Findings

The stomach and small/large intestines are more commonly involved. The gall bladder was also rarely implicated [31,45,47,50]. The disease may present as single or multiple elevated lesions or ulcers with hemorrhage and edema, measuring 1–2 cm in size [34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51].

2.2.2. Histology

The disease is usually limited to the lamina propria, featuring expansion by confluent, generally non-destructive infiltrates of mostly medium-sized atypical lymphoid cells with irregular nuclei and pale granular cytoplasm. This contrasts with iITCL, where small atypical lymphoid cells are more common, and the cytoplasm is agranular. Epithelial invasion with destruction and displacement of intestinal glands can rarely occur. Mucosal ulceration and focal necrosis are occasionally present. The muscularis mucosae is usually intact, but may be involved. There is no angiocentricity or angioinvasion. Admixture with other inflammatory cells is usually present (Figure 2) [3,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51].

2.2.3. Immunophenotype

By definition, the atypical lymphoid cells do not express TCR antigens and surface CD3. They frequently express CD56 and cytotoxic effector proteins TIA1 and granzyme B. CD2, CD7, CD8, and cytoplasmic CD3 may be expressed. The Ki67 positivity rate is usually low (<10%) but may be higher and up to 80% [3,34,36,37,38,42,44,46,49,50]. The significance of this difference in Ki67 positivity rate from iITCL is unknown.

2.2.4. Etiology and EBV Status

The etiology of iINKLPD is unknown, though Helicobacter pylori (HP) infection has been suggested to play a role, as response of iINKLPD to anti-HP treatment has been reported [3,28,35,40,44]. This, however, was not universally observed in the reported cases. In the fifty-six reported cases, all were EBV-negative. Though the number of cases reported was too small to be conclusive on the role of EBV in iINKLPD, it appears that EBV is probably not etiologically or pathogenetically related to iINKLPD.

2.2.5. Neoplastic or Non-Neoplastic?

Unlike iITCL, the biological nature of iINKLPD has not been clearly defined. Among the fifty-eight reported cases, there was no observation of distant dissemination, progression, or transformation of the disease. However, genetic alterations, including mutations in JAK3, RUNX1, CIC, ERBB4, and SETD5, were reported in iINKLPD [3,28,49,50]. Phosphorylated STAT3 [3,50] and STAT5 [8] proteins had also been demonstrated in some cases of iINKLPD. These genetic and epigenetic anomalies point to a possible neoplastic nature of iINKLPD. However, the small number of reported cases with these genetic and epigenetic changes precludes making definitive conclusions. The biological nature of iINKLPD requires further study on a larger number of cases.

2.2.6. Treatment

Among the fifty-eight reported cases, thirty-six were not given any specific treatment, four received surgery, seven received chemotherapy (with two given concomitant bone marrow transplant), one received anti-HP therapy, and there were ten cases without a reported treatment modality. Despite the treatment modality, the indolent course of persistent or relapsing disease appeared unaffected [34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50]. More work is required on a greater number of cases for a better understanding of the clinical outcome and optimal management of iINKLPD.

2.3. Differential Diagnoses of iITCL and iINKLPD from Other Intestinal NK- or T-Cell Lymphomas

The major differential diagnoses (DDX) are monomorphic epitheliotropic intestinal T-cell lymphoma (MEITCL), enteropathy-associated T-cell lymphoma (EATCL), and primary GI extranodal NK/T-cell lymphoma (ENNKTL) of the intestine. Intestinal metastasis from primary non-GI ENNKTL may also cause diagnostic confusion, but can be distinguished by the presence of a primary (nasal or other non-nasal sites) in another location. MEITCL, EATCL, and GI ENNKTL can be distinguished by their distinctive clinical manifestations, aggressive behavior, high-grade morphology, immunophenotypic, and genetic differences. In EATCL, there is often histological evidence of residual coeliac disease. Primary GI ENNKTL may be distinguished by characteristic histological evidence of frequent angiocentricity, angioinvasion, and extensive geographic necrosis. Further, EBV is always positive in ENNKTL, in contrast to the usual EBV negativity in iITCL and almost always EBV negativity in iINKLPD [52,53,54,55]. A summary of the differences among these entities is depicted in Table 1.

3. Indolent Non-Intestinal NK- or T-Cell LPD

This review uncovered 11 cases of indolent NK- or T-cell LPD that arose from non-intestinal sites. Four cases occurred in the nose, one in the nasopharynx (NP), three in the skin, one in the lymph node, one in the pericardium, and one in the vagina [50,56,57,58,59,60,61,62,63,64,65]. All cases were characterized by indolent clinical behavior of persistent or relapsing disease over long periods. Four cases were of T-cell lineage (two nose, one pericardium, one lymph node), and seven were of NK-cell lineage (two nose, three skin, one NP, and one vagina) [50,56,57,58,59,60,61,62,63,64,65]. Apart from the EBV-unknown NK-cell NP case [50] and the EBV-negative vaginal case [65], the remaining four T-cells (one lymph node, two nose, and one pericardium) and five NK-cells (two nose and three skin) were all EBV-positive. There was an indolent NKLPD of the skin, which was not tested for EBV at presentation but progressed to an EBV+ ENNKTL after a prolonged relapsing disease [58]. This case is particularly intriguing, as it raises the issue of whether the timing of EBV infection is a significant factor in the disease. Contracting EBV later in the course of the indolent disease may be a triggering event in disease progression. The rate of EBV-positivity among indolent non-intestinal NK- or T-cell LPD was 82% (9/11).
The majority (5/6 tested cases, 83%) [59,60,61,62,63,64] showed a high Ki67 positivity rate, with a reported rate of over 90% in a pericardial case [64]. Two NK EBV-positive cases of the skin showed high-grade transformation to ENNKTL (2/2, 100%) after long durations of indolent disease [57,58]. This compares with the overall lower rate of disease transformation in iITCL (5/86, 6%) [18,19,22], and that none of the nineteen EBV-negative iITCL and thirty-nine EBV-negative iINKLPD cases resulted in disease progression or transformation [4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50].
It appears that EBV-positivity is more prevalent in indolent non-intestinal NK- or T-cell LPD. They showed a higher KI67 proliferation index [59,60,61,62,63,64] and a higher rate of disease progression [57,58]. It may be argued that indolent EBV-positive non-intestinal NK- or T-cell LPDs should not be compared with other indolent EBV-negative intestine counterparts and should be grouped together with the high-grade primary GI EBV-positive ENNKTL [52,55]. However, ENNKTL is clearly different from indolent EBV+ NK- or T-cell LPD in clinical behavior, histology, immunophenotype, genetics, and outcome and should be separately categorized [52,55]. Despite this, indolent EBV+ NK- or T-cell LPDs can mimic some ENNKTL with a predominant small cell component morphologically and immunophenotypically [52,55]. This may cause great diagnostic difficulty without clinical follow-up. The indolent EBV+ NK- or T-cell LPD may also cause confusion with chronic active EBV disease (CAEBV). The former, however, could be distinguished by its lack of severe systemic symptoms and deranged liver functions at presentation that are characteristic of CAEBV [55]. It should also be mentioned that indolent EBV+ T-cell LPDs of the skin may be confused with various other cutaneous lymphomas or LPDs, which are also often indolent. The latter are distinguishable by always being negative for EBV. Since the hitherto number of reported cases of indolent EBV+ non-intestinal NK- or T-cell LPD is so far very small, it is not possible to define this as a distinctive biologic entity. Further work on many more cases is required for elucidation on the biological nature and role of EBV in these entities. Table 2 summarizes the miscellaneous features of the nine reported EBV+ indolent non-intestinal NK- or T-cell LPD.

4. Indolent T-Lymphoblastic Proliferation (iTLBP)

iTLBP was first described in 1999 in the upper aerodigestive tract of a male subject who remained indolent and stable for over 16 years without treatment [32,66,67]. iTBLP is rare, and about 50 cases have been reported in various nodal and non-nodal sites. The latter includes mandibular, cervical, supraclavicular, parotid, inguinal, abdominal, liver, adrenal, retroperitoneal, nasopharyngeal, and mediastinal locations [32,66,67,68]. iTBLP may affect reactive lymph nodes [68], occurs in Castleman disease, myasthenia gravis, paraneoplastic autoimmune multiorgan syndrome, and may be associated with neoplasms (hepatocellular carcinoma, dendritic follicular cell sarcoma, and acinic cell carcinoma) [32,66,67,68]. The clinical course is benign and indolent and does not require treatment. It is characterized histologically as non-destructive tumor-like, tumor-infiltrating lymphocyte-like, or focal cellular cluster (>50 cells) lesions [66]. The cells are small to medium-sized and lack significant atypia. Immunophenotypically, they are positive for Tdt and CD3, with variable positivity for CD1a, CD4, CD7, CD8, CD10, CD34, and CD99. This immunophenotype is in keeping with that of a common lymphoid precursor [66,67,68]. Genotypically, clonal TCR rearrangement is not present. The most important DDX is T-cell lymphoblastic lymphoma (TLBL). TLBL is distinguishable by tissue destruction, larger atypical lymphoblastic cells, aberrant immunophenotypic features, including expression of LMO2, and presence of clonal TCR rearrangement. The rarity of TLBL in adults should also be helpful in distinguishing it from iTBLP in adult patients. It is important to recognize the association of iTBLP in a variety of malignant tumors, in order to avoid confusion and misinterpretation [66,67,68].

5. Indolent Cutaneous LPD

Many cutaneous T-cell lymphomas or LPDs are clinically indolent and include primary cutaneous CD4-positive small or medium T-cell LPD (PcutCD4+TLPD), primary cutaneous acral CD8-positive T-cell LPD (PcutacCD8+TLPD), mycosis fungoides, lymphomatoid papulosis, and primary cutaneous anaplastic large cell lymphoma. PcutCD4+TLPD was a provisional entity in the 2017 WHO Classification, and PcutacCD8+TLPD was originally designated as a lymphoma. These are recently reclassified as LPD due to the benign indolent clinical course. These two entities are highlighted below.

5.1. PcutCD4+TLPD

This was a provisional entity in the 2017 revised fourth edition of the WHO Classification [32,69]. It is currently designated an LPD because of the benign indolent clinical behavior, with spontaneous regression in about 30% of cases [32,69,70,72]. It is a clonal disease, and TCR gene rearrangement is demonstrable in the majority of tested cases [70]. It affects a wide age range, with a median of 59 years. Both sexes are affected almost equally. Clinically, it affects most commonly the head and neck and presents as an asymptomatic erythematous solitary nodule and less frequently as a tumor, papule, macule, or plaque, with a size ranging from 4 to 60 mm. Histologically, two patterns were reported. The entire dermis is involved in one pattern, sometimes with extension to the subcutis. The other pattern features a subepidermal band-like infiltrate of the superficial dermis. Epidermotropism and folliculotropism may be present, rendering mycosis fungoides a differential diagnosis. The infiltrate consists mostly of small to medium atypical lymphoid cells and contains no more than 40% large cells. Immunophenotypically, the lymphoid cells are CD3+, CD4+, CD8−, CD30−, follicular T-helper cell markers+ (mostly PD-1+) and low Ki67 proliferation index. Reactive B cells and CD8+ T cells may be present. The prognosis is excellent. Treatment with intralesional steroids, excision, or radiotherapy is effective, and spontaneous remission without treatment occurs in 30% cases. The major DDX are mycosis fungoides, primary cutaneous marginal zone lymphoma, and cutaneous lymphoid hyperplasia [32,70,72].

5.2. PcutacCD8+TLPD

It was designated as a lymphoma in the 2017 revised fourth edition of the WHO Classification and has been recently regarded as an LPD in view of the indolent benign clinical behavior. It is a slow-growing, solitary, reddish-purple skin nodule or plaque measuring up to several centimeters. It affects acral sites, including the face, ear, nose, hands, or feet. It is histologically characterized by a dense, monotonous, atypical dermal lymphoid infiltrate consisting of medium-sized cells. Extension into the subcutis is common. Immunophenotypically, the lymphoid cells are CD3+, CD4−, CD8+, CD30−, cytotoxic cell phenotype+ (TIA1+ mostly), CD56−, and PD1-. CD68 is positive, showing the characteristic Golgi-dot-like positivity. Ki67 proliferation index is low. Clonal TCR rearrangement is present in nearly all cases. The prognosis is excellent, with complete remission after excision or local irradiation [32,71,73].

6. Conclusions

Indolent NK- or T-cell LPD are less recognized and characterized, compared to the B-cell counterparts. The latter include B-cell lymphocytic lymphoma/leukemia, marginal-zone lymphoma of mucosa-associated lymphoid tissue, lymphoplasmacytic lymphoma, indolent mantle cell lymphoma (leukemic type), and follicular lymphoma. They are well delineated morphologically, immunophenotypically, genotypically, and nosologically [81]. iITCL was first described three decades ago, followed almost a decade later by reports of iINKLPD. The indolent clinical behavior of these entities has been the major confounding factor in delineating their biological nature. The significant morbidities, ability to disseminate, potential for disease progression and transformation, and multiple genetic alterations identified in iITCL have led to its recent recognition as a lymphoma [2,27,31]. iINKLPD, on the other hand, appears less definitive. However, the frequent presence of JAK3 and other genetic mutations, as well as the expression of the phosphorylated STAT3 and STAT5 proteins, points to the possible neoplastic nature of iINKLPD [3,8,28,49,50].
The role of EBV in these indolent NK- or T-cell lymphomas or LPD is also perplexing. Though it is commonly believed that EBV-negativity is a feature of iITCL and iINKLPD, the reports of EBV+ iITCL challenge this commonplace conviction [7,26,29]. The more frequent reports of EBV-positivity in indolent non-intestinal NK- or T-cell LPD cast a more conjectural aura on this belief [56,57,58,59,60,61,62,63,64]. The small number of reported cases of iITCL that were tested and confirmed to be EBV-negative, amid an even larger number of cases with unknown EBV status (63/85,74%), raises the need for accumulation of further evidence before a firm dogma can be made on the role of EBV in these entities. Ki67 proliferation index is low in most iITCL cases. However, it is higher in iINKLPD and indolent non-intestinal EBV+ NK- or T-cell LPD. This finding is interesting, but the significance is unknown.
The recognition of iTBLP is eye-opening since the presence of lymphoblasts often conveys the notion of proliferation and neoplasia. The indolent behavior of iTLBP warrants greater awareness of the entity in order to avoid unnecessary radical therapy. Though many cutaneous T-cell lymphomas are indolent in behavior, PcutCD4+LPD and PcutacCD8+LPD have recently been reclassified as LPD instead of lymphoma due to the uniformly excellent clinical behavior. Such redesignation is important for better recognition of their biological nature and avoidance of over-treatment.

Funding

This work received no external funding.

Institutional Review Board Statement

This review article requires no IRB approval for the purposes of literature review and educational examples.

Data Availability Statement

The original contributions presented in this study are included in the review article material. Further inquiries can be directed to the corresponding author.

Acknowledgments

The author thanks Xingen Wang, Department of Pathology, Peking University Shenzhen Hospital, for supplying images of Figure 1 and Figure 2. These images were taken from the teaching set of the Peking University Shenzhen Hospital.

Conflicts of Interest

The author declares no conflicts of interest.

Abbreviations

The following abbreviations are used in this manuscript:
DDXdifferential diagnosis
EATCLenteropathy-associated T-cell lymphoma
EBVEpstein–Barr virus
EBEREBV encoded small RNA
ENNKTLextranodal natural killer-/T-cell lymphoma
GIgastrointestinal
iINKLPDindolent intestinal natural killer-cell lymphoproliferative disease
iITCLindolent intestinal T-cell lymphoma
LPDlymphoproliferative disease
MEITCLmonomorphic epitheliotropic intestinal T-cell lymphoma
NGS next-generation sequencing
NKnatural killer
PcutacCD8+TLPDprimary cutaneous acral CD8+ T-cell LPD
PcutCD4+TLPDprimary cutaneous CD4+ T-cell LPD
TCRT-cell receptor
TLBLT-cell lymphoblastic lymphoma

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Lymphatics 03 00041 g001
Figure 1. (A) Male, 46 years, vague abdominal symptoms. Multifocal GI involvement. Colonic biopsy. (A) Non-destructive mucosal atypical lymphoid infiltrates. The glands were displaced but not invaded by the infiltrates. H&E, ×50. (B,C) Mucosal small atypical lymphoid cells infiltrate. Focal intraepithelial involvement is present. The atypical cells showed mildly enlarged and irregular nuclei. H&E, (B) ×200, (C) ×400. (D) CD3+, ×100. (E) Ki67 low, ×100. (F) Aberrant CD20+, ×100.
Figure 1. (A) Male, 46 years, vague abdominal symptoms. Multifocal GI involvement. Colonic biopsy. (A) Non-destructive mucosal atypical lymphoid infiltrates. The glands were displaced but not invaded by the infiltrates. H&E, ×50. (B,C) Mucosal small atypical lymphoid cells infiltrate. Focal intraepithelial involvement is present. The atypical cells showed mildly enlarged and irregular nuclei. H&E, (B) ×200, (C) ×400. (D) CD3+, ×100. (E) Ki67 low, ×100. (F) Aberrant CD20+, ×100.
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Lymphatics 03 00041 g002
Figure 2. Male, 48 years, abdominal pain. Jejunal biopsy. (A,B) Non-destructive mucosal medium-sized atypical lymphoid cell infiltrates with pale granular cytoplasm. There was no glandular invasion. Involvement of muscularis mucosae in (B). H&E, ×200. (C) CD56+, ×100. (D) CD3+, ×100. (E) Ki67 high (about 60%), ×100.
Figure 2. Male, 48 years, abdominal pain. Jejunal biopsy. (A,B) Non-destructive mucosal medium-sized atypical lymphoid cell infiltrates with pale granular cytoplasm. There was no glandular invasion. Involvement of muscularis mucosae in (B). H&E, ×200. (C) CD56+, ×100. (D) CD3+, ×100. (E) Ki67 high (about 60%), ×100.
Lymphatics 03 00041 g002
Table 1. Comparative features of gastrointestinal NK-/T-cell lymphomas and LPD.
Table 1. Comparative features of gastrointestinal NK-/T-cell lymphomas and LPD.
iITCLiINKLPDENNKTLMEITLEATL
Age (years)CD4+: Median 51
CD8+: Median 45		30–9035–58Median 54–67Median 61
SexM > FM > FM > FM > FM > F
Predominant
sites involved		Small intestine, colonStomach, small intestine, colon, gall bladderGI tractSmall intestineSmall intestine (mostly jejunum)
MultifocalityCommonYes27%20–35%32–54%
Enteropathy associationNoNoNoNo80%
MetastasisBM, PB, tonsil, mesenteric LNRarely mesenteric LNMultiple extraintestinal sites, frequently Stage IVLN, lung, liver, brain, skinLN, BM, lung, liver
Transformation ReportedNRNANANA
Depth involvedMucosa, sometimes also MM and SMMucosaFull thicknessFull thicknessOften full thickness
HistologySmall/medium atypical cells, non-destructive dense infiltrate, no/rare epithelial invasion, no angioinvasionMedium atypical cells, small nucleoli, pale granular cytoplasm, circumscribed confluent infiltrate, glands displaced, epithelial invasion +/−, necrosis +/−Range of atypical cells, geographic necrosis, epithelial invasion, angiocentricity, angioinvasion, angiodestruction Monotonous atypical cell infiltrates, necrosis, epithelial invasion, severe inflammatory backdrop, “starry sky” appearanceRange of atypical cells, epithelial invasion, angioinvasion, angiodestruction, features of CD
Molecular/genetic alterationsSTAT3, JAK2,, JAK2::STAT3 fusion, STAT5, SOCS1, KMT2D, TET2, DNMT3A, EZH2, TNFAIP3, IL2, RHOH, TNIP3, TCRJAK3, RUNX1T1, CIC, ERB4, SETD5PRDM1, PTPRK, HACE1, FOXO3, STAT3, JAK3, STAT5B, BCOR, KMT2D, ARID1A, EP300, TCR (in T-cell type)Myc, SETD2, STAT3, STAT5, JAK1, KAK3, TCRJAK1, STAT3, TET2, KMT2D, DOX3X, TNFA1P3, TNIP3, POT1, TP53, CD58, FAS, B2M, TCR
ImmunophenotypeCD3+, CD4+CD8−, CD4−CD8+, CD4+CD8+, CD4−CD8−, TCR+, KI67 low *CD56+, CD2+, cCD3+, CD7+, TIA1+, GZB+, TCR-, Ki67 high CD56+ (NK-cell type), cCD3+, sCD3+ (T-cell type), CD2+, TIA1+, GZB+, perforin+, TCR- (in NK-cell type), TCR+ (in T-cell type), Ki 67 highCD2+, sCD3+, CD7+, CD8+, CD56+/−, TIA1+, TCR+, Ki67 highCD3+, CD7+, TIA1+, GZB+, perforin+, Ki67 > 50%, CD30+/EMA+ (in anaplastic cases)
EBVNegative @NegativePositiveNegativeNegative
Footnote: * Some cases reported Ki67 high, @ Some cases reported EBV+, +: positive, − negative, +/−: weak or focal positive, cCD3: cytoplasmic CD3, CD: Coeliac disease, BM: bone marrow, EATL: enteropathy associated T-cell lymphoma, ENNKTL: extranodal NK-/T-cell lymphoma, F: female, GZB: granzyme B, iINKLPD: indolent intestinal NK-cell lymphoproliferative disorder, iITCL: indolent intestinal T-cell lymphoma, LN: lymph node, M: male, MEITL: monomorphic epitheliotropic intestinal T-cell lymphoma, MM: muscularis mucosae, NA: not applicable, NR: not reported, PB: peripheral blood, sCD3: surface CD3, SM: submucosa, TCR: T-cell receptor.
Table 2. Summary of reported EBV+ non-intestinal indolent T- and NK-cell LPDs.
Table 2. Summary of reported EBV+ non-intestinal indolent T- and NK-cell LPDs.
Series
(Reference,
Year)		SexAgeLPD
Duration (Years)		Site(s)Disease Progression Px of
Progressed
Disease		Clinical
Outcome		Histology
of LPD		ImmunophenotypeGenotypeLineageEBV/EBER
of LPD		Ki67
Rahemtullah et al. [54]
(2008)		M714neck
LN		EBV+ BCL with plasmacytic differentiationCTDOD
(66 m)		LGCD2+, CD3+, CD5+,
CD7+, CD4+, CD20+,
CD30+(dim),
CD56+(dim)		TCR: GL
Ig: polyclonal		T+
(EBV clonal)		NR
Watabe
et al. [55]
(2009)		F3910skin
(legs)		ENNKTL,
nasal type (skin)		CTDOD
(128 m)		LG *CD3+, CD56+,
GZB+, CD8+/−,
perforin +/−		TCR: GLNK+
(LMP+)
(EBV biclonal)		NR
Seishima FM
et al [56]
(2010)		F6011.5skin
(lip and cheek)		EBV+ ENNKTL,
nasal type
(nose and multiple skin sites)		CTDOD
(146m)		LG *CD56−, CD4+/−,
CD8+/−,
cytotoxic (ND)		NRNK
(CD56 turned + on progression)		NRNR
Jiang QP
et al [57]
(2012)		F7810noseNPNAAWDLGCD3+, CD56+,
Cytotoxic+,
CD20+		TCR: GL
Ig: GL		NK+
(EBV
genome)		60%
Zuriel D
et al [58]
(2012)		F5522skin
(recurrent, right upper arm)		NPNAAWD (recurrence 192 m and 264 m, skin right upper arm)LGCD2+, CD3+,
cytotoxic+,
CD56+ (at 264 m)
Ki67 > 90%		TCR: GLNK+90%
Tabeanelli V
et al [59]
(2014)		F5213noseNPNAAWD
at
156 m		LGCD2+, CD3+, CD5+,
CD7+, CD56+,
βF1+, TCR α/δ+,
cytotoxic+,
Ki67 (moderately high) 		TCR: clonalT+Moderate high
Zhang QF
et al [60]
(2016)		M5320noseNRNAAWD
at
242 m		LGCD3+, CD56+,
cytotoxic+,
Ki67(80%)		NRNK+80%
Devins K
et al [61]
(2018)		F71long standingnoseNRNAAWD
(many years)		LGCD2+, CD3+,
CD3+/−, CD5+/−,
CD7+/−, CD56−
cytotoxic+,
Ki67 (<1%)		TCR: clonal
KIT mutation+		T+<1%
Wang Z et al. [62] (2020)M6419PericardiumNPNAAWLGCD3+,CD30+,CD43+,
TIA1+, MUM1+, BCL2+		TCR: clonalT+>90%
AW: alive and well; AWD: alive with disease; BCL: B-cell lymphoma; CT: chemotherapy; DOD: died of disease; ENNKTL: extranodal NK/T-cell lymphoma; GZB: Granzyme B; LG: low grade; LN: lymph node; LPD: lymphoproliferative disease; NA: not applicable; NP: no progression of disease; NR: not reported; TCR: T-cell receptor gene; *: interpreted from published images; +: positive, +/−: weak or focal positive.
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Ng, C.S. Indolent T- and Natural Killer-Cell Lymphomas and Lymphoproliferative Diseases—Entities in Evolution. Lymphatics 2025, 3, 41. https://doi.org/10.3390/lymphatics3040041

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Ng CS. Indolent T- and Natural Killer-Cell Lymphomas and Lymphoproliferative Diseases—Entities in Evolution. Lymphatics. 2025; 3(4):41. https://doi.org/10.3390/lymphatics3040041

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Ng, Chi Sing. 2025. "Indolent T- and Natural Killer-Cell Lymphomas and Lymphoproliferative Diseases—Entities in Evolution" Lymphatics 3, no. 4: 41. https://doi.org/10.3390/lymphatics3040041

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Ng, C. S. (2025). Indolent T- and Natural Killer-Cell Lymphomas and Lymphoproliferative Diseases—Entities in Evolution. Lymphatics, 3(4), 41. https://doi.org/10.3390/lymphatics3040041

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