Introduction
Lung cancer is the leading cause of cancer-related
mortality and one of the most commonly diagnosed types of cancer
both in China and worldwide, accounting for an estimated 2.2
million new cases (11.4%) and 1.8 million deaths (18.0%) worldwide
in 2020 (1,2). Lung squamous cell carcinoma (LUSC) is
the second most prevalent histological subtype of lung cancer,
accounting for 25–30% of all lung cancer cases worldwide (3). Although advances in targeted therapy
and immunotherapy have improved outcomes for lung adenocarcinoma
(LUAD) (4–6), the prognosis for patients with LUSC
remains unsatisfactory (7).
Driver gene alterations, such as EGFR,
anaplastic lymphoma kinase (ALK) and proto-oncogene
tyrosine-protein kinase 1 (ROS1) are commonly observed in
LUAD but not in LUSC (8–10). Immunotherapy is currently the
preferred treatment choice for patients with advanced or metastatic
LUSC, exhibiting programmed cell death ligand-1 expression of ≥1%.
However, only ~20% of cases respond to this type of therapy
(11–13). Consequently, chemotherapy continues
to be a cornerstone of LUSC treatment (9,14).
LUSC remains a therapeutically challenging malignancy and therefore
identifying reliable molecular biomarkers capable of predicting
chemotherapy responsiveness and guiding clinical decision-making
are of great importance.
In the present study, a large cohort of patients
with LUSC were retrospectively analyzed. Non-negative matrix
factorization (NMF) clustering was employed to identify the
molecular subtypes of LUSC based on genomic alteration patterns.
Furthermore, the predictive performance of NMF-derived genomic
signatures in predicting the efficacy of chemotherapy was also
evaluated. Overall, the present study aimed to identify a feasible
and reliable genomic signature to identify patients with LUSC more
likely to benefit from chemotherapy, thereby ensuring more precise
and individualized treatment strategies.
Materials and methods
Patients and samples
Patients who met the following inclusion criteria
were retrospectively analyzed: i) Patients diagnosed with LUSC
according to World Health Organization criteria (15); ii) those who underwent
next-generation sequencing (NGS) analysis at West China Hospital
(Sichuan, China) between January 2018 and December 2020
(identification period). The observation period was measured from
treatment initiation until radiographically confirmed disease
progression or the administrative censoring date of January 2023;
iii) aged >18 years; and iv) with tumor cell content ≥20% in
formalin-fixed, paraffin-embedded (FFPE) tissue sections (3-µm
thickness), as determined by an experienced pathologist on
H&E-stained slides. No additional exclusion criteria were
applied. Additionally, a cohort of patients with LUSC who received
first-line chemotherapy were also retrospectively included to
evaluate the performance of the genomic signature developed in the
present study. All samples were analyzed using a 56-gene panel
(LungCore; Burning Rock Biotech, Ltd). This panel was part of
standard routine care and covered the entire exon regions of 56
lung cancer-related genes which was previously described in our
published article (16). This was a
retrospective study, which utilized existing clinical records, and
all patient data and samples were rigorously de-identified prior to
analysis. The full study protocol, which included a waiver of the
requirement for informed consent, was reviewed and approved by the
Ethics Committee of West China Hospital (Sichuan, China) and
conducted according to the local ethical guidelines (approval no.
2022-1849).
DNA extraction and capture-based
targeted DNA sequencing
Genomic DNA was extracted from FFPE tumor tissues
using QIAsymphony® DSP DNA Mini Kit (cat. no. 937236;
Qiagen GmbH), according to the manufacturer's instructions. A total
of 200 ng of DNA was used for the preparation of the NGS library.
DNA integrity was verified by 1.5% agarose gel electrophoresis. The
concentration of DNA was quantified using the Qubit dsDNA HS Assay
Kit on a Qubit 3.0 fluorometer (Thermo Fisher Scientific, Inc.).
DNA was fragmented using the Covaris M220 system (Covaris, LLC).
The fragmented DNA was end-repaired and 3′-adenylated in a combined
reaction, followed by adapter ligation using T4 DNA ligase (Burning
Rock Biotech, Ltd.). Both enzymatic reactions were carried out in
PCR tubes with thermal cycling under a heated lid (85°C). DNA
fragments ranging from 200 to 400 bp were purified using the
Agencourt AMPure XP Kit (Beckman Coulter, Inc.), followed by
hybridization with capture probes; specifically, 50 ng/µl of
capture probe baits were co-incubated with DNA fragments in a PCR
instrument at 65°C for 16–24 h. This was followed by hybrid
selection with magnetic beads and PCR amplification with DNA
polymerase (Burning Rock Biotech, Ltd.). PCR amplification was
performed with an annealing temperature of 60°C for 12 cycles with
Illumina-provided i5/i7 primers. Library quality was assessed using
the Qubit dsDNA HS Assay Kit (cat. no. Q32854; Invitrogen; Thermo
Fisher Scientific, Inc.) and the Agilent 2100 Bioanalyzer System
(Agilent Technologies, Inc.). Indexed libraries were primarily
sequenced on the Miseq (Illumina, Inc.) platform. A subset of 66
libraries was sequenced on the MiniSeq (cat. no. SY-410-1003;
Illumina, Inc.) platform due to instrument availability. The
loading concentration of the final library was 14 pM for Miseq and
1.5 pM for MiniSeq. All sequencing was performed using 150-bp
paired-end reads.
Sequencing data analysis
Sequencing data were mapped to the human reference
genome (hg19) using Burrows-Wheeler aligner 0.7.10 (https://sourceforge.net/projects/bio-bwa/files/)
(17). Local realignment and
variant calling were performed using the Genome Analysis Toolkit
version 3.2 (18) and VarScan
software 2.4.3 (Genome Institute at Washington University)
(19). Variants were filtered using
the VarScan filter pipeline, requiring a minimum depth of 100×.
From FFPE tumor tissue, at least five supporting reads for short
insertions and deletions (indels) and eight for single nucleotide
variations (SNVs) were required. Variants with a population
frequency of >0.1% were considered as common single-nucleotide
polymorphisms and excluded according to the Exome Aggregation
Consortium (https://gnomad.broadinstitute.org), 1000 Genomes
Project (https://www.internationalgenome.org/), dbSNP
(https://www.ncbi.nlm.nih.gov/snp/)
and ESP6500SI–V2 (https://genome.ucsc.edu/cgi-bin/hgTables?db=hg19&hgta_group=varRep&hgta_track=evsEsp6500&hgta_table=evsEsp6500&hgta_doSchema=describe+table+schema)
databases. The remaining variants were annotated using ANNOVAR
(2016-02-01 release) (20) and
SnpEff v3.6 (21). DNA
translocation was detected using Factera v.1.4.3 (22). Indels, copy number variations (CNVs)
and large genomic rearrangements (LGRs) were identified as
previously described (23,24).
NMF analysis
Data clustering was performed using NMF based on
Euclidean distance (25,26). Non-synonymous SNVs, indels, CNVs and
structural variations were included in the NMF clustering analysis.
Patients harboring only synonymous SNVs or undetectable genomic
alterations were excluded from the analysis. The R package 'NMF'
(version 0.22.0) was implemented in R (version 3.4.0; R Foundation
for Statistical Computing) to estimate the optimal factorization
rank using Lee and Seung's algorithm with 2:8 ranks (27). A marked decrease in the cophenetic
correlation coefficient was observed between ranks 4 and 5
(28), therefore rank 4 was
selected as the optimal value, thus resulting in four
subgroups.
Validation data collection
Sequencing data from patients with LUSC were
downloaded from The Cancer Genome Atlas (TCGA; http://portal.gdc.cancer.gov/) database using the
R package ‘TCGAbiolinks’. The clinical characteristics of patients,
including age, sex tumor stage, progression-free survival (PFS) and
patient outcomes were also collected. The prognostic value of the
NMF-based model was validated in the TCGA LUSC cohort.
Statistical analysis
All analyses were performed using R statistics
packages (R v3.4.0; Posit Software). The differences between the
two groups were compared using Fisher's exact test for categorical
variables. For comparisons involving more than two groups, the
Kruskal-Wallis test was first applied. When the overall test was
significant, pairwise post-hoc comparisons were performed using the
Wilcoxon rank-sum test with Holm correction to control for multiple
testing. PFS was assessed using the Kaplan-Meier method, and
differences between survival curves were compared using the
log-rank test. P<0.05 was considered to indicate a statistically
significant difference.
Results
Patient characteristics
A total of 317 patients with LUSC were included in
the present study. The majority of patients were men (89.9%;
285/317), aged ≥60 years (67.2%; 213/317) and were former or
current smokers (57.4%; 182/317). Histologically, 55.2% (175/317)
of tumors were classified as keratinizing squamous cell carcinoma
(KSCC), 28.7% (91/317) as non-KSCC (NKSCC), while 16.1% (51/317)
were of unknown subtype. The distribution of tumor stage varied,
with 3.2% (10/317) of patients diagnosed with stage I, 6.6%
(21/317) with stage II, 28.7% (91/317) with stage III, 27.8%
(88/317) with stage IV, while 33.8% (107/317) of cases were of
unknown stage. Among the 317 patients, 35 received first-line
chemotherapy. Of these, 91.4% (32/35) were men and 88.6% (31/35)
were former or current smokers. Histologically, 65.7% (23/35) were
diagnosed with KSCC, 25.7% (9/35) with NKSCC and 8.6% (3/35) were
of unknown subtype. In terms of disease stage, 5.7% (2/35) had
stage I disease, 25.7% (9/35) stage II, 34.3% (12/35) stage III,
28.6% (10/35) stage IV and 5.7% (2/35) had unknown stage. The
detailed clinical characteristics of patients are presented in
Table I. The two cohorts showed no
statistically significant differences in terms of age (P=0.101),
sex (P=1.000), subtype (P=0.557), T stage (P=0.948), N stage
(P=0.180) and M stage (P=0.341). However, marginally significant
differences were observed in terms of smoking history (P=0.048) and
tumor stage (P=0.049). In addition, the clinical characteristics of
patients from TCGA database and those who received
radiochemotherapy are shown in Tables
SI and SII.
 | Table I.Baseline characteristics of 317
patients with lung squamous cell carcinoma and chemotherapy
regimens in the chemotherapy cohort. |
Table I.
Baseline characteristics of 317
patients with lung squamous cell carcinoma and chemotherapy
regimens in the chemotherapy cohort.
| Characteristic | Total (n=317) | Chemotherapy
(n=35) | P-value |
|---|
| Age, years |
|
| 0.101 |
| Mean,
SD | 64.1 (9.7) | 61.2 (9.6) |
|
| Median,
IQR | 64.0 (56.0,
71.0) | 63.0 (53.5,
67.0) |
|
| Sex |
|
| 1.000 |
|
Female | 32 (10.1) | 3 (8.6) |
|
|
Male | 285 (89.9) | 32 (91.4) |
|
| Subtype |
|
| 0.557 |
|
KSCC | 175 (55.2) | 23 (65.7) |
|
|
NKSCC | 91 (28.7) | 9 (25.7) |
|
|
Unknown | 51 (16.1) | 3 (8.6) |
|
| Smoker |
|
| 0.048 |
| No | 57 (18.0) | 3 (8.6) |
|
|
Yes | 182 (57.4) | 31 (88.6) |
|
|
Unknown | 78 (24.6) | 1 (2.9) |
|
| Stage |
|
| 0.049 |
| I | 10 (3.2) | 2 (5.7) |
|
| II | 21 (6.6) | 9 (25.7) |
|
|
III | 91 (28.7) | 12 (34.3) |
|
| IV | 88 (27.8) | 10 (28.6) |
|
|
Unknown | 107 (33.8) | 2 (5.7) |
|
| T stage |
|
| 0.948 |
| T1 | 12 (3.8) | 2 (5.7) |
|
| T2 | 50 (15.8) | 9 (25.7) |
|
| T3 | 47 (14.8) | 9 (25.7) |
|
| T4 | 93 (29.3) | 14 (40) |
|
|
Unknown | 115 (36.3) | 1 (2.9) |
|
| N stage |
|
| 0.180 |
| N0 | 39 (12.3) | 12 (34.3) |
|
| N1 | 26 (8.2) | 5 (14.3) |
|
| N2 | 74 (23.3) | 8 (22.9) |
|
| N3 | 59 (18.6) | 9 (25.7) |
|
|
Unknown | 119 (37.5) | 1 (2.9) |
|
| M stage |
|
| 0.341 |
| M0 | 121 (38.2) | 23 (65.7) |
|
| M1 | 79 (24.9) | 10 (28.6) |
|
|
Unknown | 117 (36.9) | 2 (5.7) |
|
| Chemotherapy
regimens | - |
| - |
| Taxane
plus platinum |
| 23 (65.7) |
|
| Taxane
(Paclitaxel) |
| 6 (17.1) |
|
|
Gemcitabine |
| 1 (2.9) |
|
|
Gemcitabine plus Platinum |
| 4 (11.4) |
|
|
Gemcitabine plus
cisplatin- |
| 1 (2.9) |
|
|
Paclitaxel plus cisplatin |
|
|
|
Genomic alterations of LUSC
Genomic alterations, including non-synonymous SNVs,
indels, CNVs, gene fusions and LGRs, were detected in 98% (311/317)
of patients (Fig. 1A). TP53
was the most commonly altered gene (91%; 287/317) followed by
PIK3 catalytic subunit (PIK3CA; 46%; 145/317), cyclin
dependent kinase inhibitor 2A (CDKN2A; 24%; 77/317) and
EGFR (17%; 53/317). CNVs were identified in 209 cases, with
the most prevalent CNVs detected in PIK3CA (38%; 120/317),
fibroblast growth factor (FGF) receptor 1 (FGFR1;
15%; 48/317) and genes located at chromosome 11q13 (11%; 35/317),
including cyclin D1 (CCND1; 11%; 35/317), FGF3
(9%; 28/317), FGF4 (8%; 25/317) and FGF19 (10%;
33/317). SNVs and indels were detected in 305 patients, and the
highest frequency was recorded in TP53 (90%; 285/317),
followed by CDKN2A (22%; 71/317), PIK3CA (14%;
45/317), PTEN (14%; 43/317), EGFR (11%; 36/317) and
Erb-B2 receptor tyrosine kinase 4 (ERBB4; 10%;
32/317). Additionally, nine fusion events were identified,
including EML4-ALK fusions in two patients, and
SEC61G-EGFR, CASC21-MYC, FGFR1-ADAM9, FGFR3-TACC3,
C12orf66-KIT and FGFR3-TACC3, FGFR1-IGFBPL1 fusions in
one patient each. Two patients carried LGRs, including RB
transcriptional corepressor 1 (RB1) in one case and
TP53 in the other.
 | Figure 1.NMF-based molecular clustering of 317
patients with LUSC. (A) NMF-based molecular clustering of patients
with LUSC, classified into four clusters (C1, C2, C3 and C4). (B)
Differences in the number of copy number variants among the four
molecular clusters (C1-4) were first assessed using the
Kruskal-Wallis test, followed by pairwise comparisons using the
Wilcoxon rank-sum test with Holm correction. *P<0.05,
****P<0.0001. NMF, non-negative matrix factorization; LUSC, lung
squamous cell carcinoma; C, cluster; Indel, insertion and deletion;
CN, copy number; CNV, copy number variation; LGR, large genomic
rearrangement; KSCC, keratinizing squamous cell carcinoma; NKSCC,
non-keratinizing squamous cell carcinoma; del, deletions; amp,
amplification. |
NMF-based clustering analysis
NMF-based clustering was performed to classify
patients according to their genomic profile. Excluded from the
analysis were two patients harboring synonymous SNVs and six with
undetectable genomic alterations. Therefore, NMF analysis was
conducted for a total of 309 patients with LUSC. These patients
were classified into the following four distinct clusters (Fig. 1A): i) Cluster 1 (C1) consisted of
129 patients characterized by TP53 alterations; ii) Cluster
2 (C2) included 116 patients with PIK3CA amp; iii) Cluster 3
(C3) composed of 33 patients characterized by amp of CCND1,
FGF19, FGF3 and FGF4; and iv) Cluster 4 (C4) included 31
patients characterized by amp of FGFR1, kinase insert domain
receptor (KDR), KIT proto-oncogene (KIT)
and platelet derived growth factor receptor α
(PDGFRA). Among the four clusters, C3 and C1 exhibited the
highest and lowest CNV frequency, respectively (Fig. 1B).
Association between different clusters
and survival outcomes in patients with LUSC
The association between NMF-based molecular clusters
and survival outcomes was subsequently investigated. Among the 317
patients with LUSC, 35 patients who received first-line
chemotherapy and had available PFS data were included in a
retrospective cohort. A single patient was excluded due to the
undetectable genetic alterations, leaving 34 patients for NMF
analysis. Of the aforementioned patients, 13, 10, 5 and 6 were
allocated into the C1, C2, C3 and C4 clusters, respectively
(Fig. 2A). No statistically
significant difference in PFS was observed among the four clusters
(P=0.12; Fig. 2B). Pairwise
comparisons further confirmed that PFS did not differ significantly
among C2, C3 and C4 (all P>0.5; Fig.
2B). Given their comparable chemotherapy outcomes and the
shared feature of gene amplification, C2, C3 and C4 were therefore
merged in a data-driven manner for subsequent analyses. Notably,
patients in C1 exhibited significantly shorter PFS compared with
those in C2/3/4 [3.5 vs. 12.5 months; P=0.018; hazard ratio (HR)
=0.35; 95% confidence interval (CI): 0.14–0.87; Fig. 2C). Additionally, tumor stage
distribution was similar among the clusters, thus indicating a
comparable background in tumor stage. (P=0.415; Fig. S1A; and P=0.293; Fig. S1B).
TP53 loss-of-function (LOF) variations
combined with NMF-based molecular clustering for PFS
prediction
The LOF alterations in TP53 are known
contributors to chemotherapy resistance in several types of cancer
(29). In the present study, the
prognostic effect of TP53 LOF in 35 patients with LUSC
treated with first-line chemotherapy was explored. In the present
chemotherapy cohort, all 29 patients (83%) harboring TP53
mutations were annotated as LOF according to the OncoKB database
(https://www.oncokb.org/gene/TP53#tab=FDA). However,
patients with TP53 mutations showed no significant
difference in PFS compared with TP53-wild-type patients
(P=0.835; Fig. S2). Considering
that truncating alterations (frameshift, splice-site, nonsense
mutations or copy number deletions) are expected to result in
complete functional loss through nonsense-mediated mRNA decay or
production of severely truncated proteins, whereas missense
mutations may exert heterogeneous effects including partial LOF,
dominant-negative or gain-of-function (30,31),
TP53 LOF was defined in the present study exclusively as
truncating alterations and did not include missense mutations in
the LOF category. Using this definition, the results revealed that
patients with TP53 LOF (n=15) exhibited significantly
shorter median PFS (mPFS) compared with those without TP53
LOF (4.8 vs. 17 months; P=0.029; HR=0.37; 95% CI: 0.15–0.93;
Fig. 3A). No significant difference
was observed in the distributions of TP53 LOF across all
clusters (P=0.389; Fig. S3A), nor
specifically among C2, C3 and C4 clusters (P=0.288) and the
distribution of TP53 LOF was also similar between C1 and
C2/3/4 clusters (P=0.728; Fig.
S3B). A comparison of TP53 background can be performed
across these clusters. Furthermore, the combined predictive value
of TP53 LOF and NMF-based molecular clustering in patients
with LUSC was evaluated. The results demonstrated that patients in
C1 with TP53 LOF exhibited worse prognosis (mPFS=2.4 months)
compared with C1 without TP53 LOF (mPFS=7.1 months), C2/3/4
with TP53 LOF (mPFS=5.3 months) and C2/3/4 without
TP53 LOF (mPFS not reached; Fig.
3B). Additionally, to refine the clustering approach, the
status of TP53 alterations and gene amps were considered,
thus resulting in the classification of 34 patients into four
subtypes. Notably, patients without TP53 LOF, but with amp
of at least one of the nine specified genes (PIK3CA, CCND1,
FGF19, FGF3, FGF4, FGFR1, KDR, KIT and PDGFRA) displayed
the longest mPFS (not reached) compared with those with TP53
LOF but without Amp(9G), who exhibited the shortest PFS (mPFS=2.6
months; Fig. 3C). Consistent
results were observed when patients with Amp(9G) and TP53
LOF were merged with those without Amp(9G) and TP53 LOF into
a single subgroup (Fig. 3D).
Multivariable Cox analysis demonstrated that the Amp(9G) combined
with TP53 LOF-based grouping was independently associated
with PFS after adjustment for tumor stage (Fig. S4).
![Prognostic value of TP53 LOF
alterations alone or in combination with non-negative matrix
factorization-based molecular clustering or gene amp status in
patients with lung squamous cell carcinoma who received first-line
chemotherapy. (A) PFS stratified by TP53 LOF status. (B) PFS
comparison among four subgroups: C1 with TP53 LOF, C1
without TP53 LOF, C2/3/4 with TP53 LOF and C2/3/4
without TP53 LOF. (C) PFS comparison among patients
harboring Amp(9G) with TP53 LOF, Amp(9G) without TP53
LOF, TP53 LOF without Amp(9G) and those without TP53
LOF and Amp(9G). (D) PFS comparison among patients harboring
TP53 LOF without Amp(9G), Amp(9G) without TP53 LOF
and others [including those with Amp(9G) and TP53 LOF and
those without Amp(9G) and TP53 LOF]. LOF, loss-of-function;
PFS, progression-free survival; C, cluster; amp, amplification;
Amp(9G), amplification of at least one of nine genes.](/article_images/ol/32/1/ol-32-01-15644-g02.jpg) | Figure 3.Prognostic value of TP53 LOF
alterations alone or in combination with non-negative matrix
factorization-based molecular clustering or gene amp status in
patients with lung squamous cell carcinoma who received first-line
chemotherapy. (A) PFS stratified by TP53 LOF status. (B) PFS
comparison among four subgroups: C1 with TP53 LOF, C1
without TP53 LOF, C2/3/4 with TP53 LOF and C2/3/4
without TP53 LOF. (C) PFS comparison among patients
harboring Amp(9G) with TP53 LOF, Amp(9G) without TP53
LOF, TP53 LOF without Amp(9G) and those without TP53
LOF and Amp(9G). (D) PFS comparison among patients harboring
TP53 LOF without Amp(9G), Amp(9G) without TP53 LOF
and others [including those with Amp(9G) and TP53 LOF and
those without Amp(9G) and TP53 LOF]. LOF, loss-of-function;
PFS, progression-free survival; C, cluster; amp, amplification;
Amp(9G), amplification of at least one of nine genes. |
Validation of NMF-based signature
To validate the aforementioned findings, DNA
sequencing data and clinicopathological characteristics of patients
with LUSC were downloaded from TCGA database. The analysis included
only patients who received chemotherapy, resulting in a validation
cohort of 99 patients (TCGA-LUSC cohort). The results showed that
TP53 LOF was associated with shorter PFS compared without
TP53 LOF (19.0 vs. 61.6 months; P=0.014; HR=0.48; 95% CI:
0.26–0.87; Fig. 4A). NMF analysis
further stratified the TCGA-LUSC cohort into the same four clusters
(Fig. S5). Furthermore, evaluation
of the combined TP53 LOF and Amp(9G) revealed that patients
with Amp(9G) but without TP53 LOF had favorable mPFS (61.6
months), while those with TP53 LOF and no Amp(9G) had worse
mPFS (18.7 months; Fig. 4B). The
Amp(9G) and TP53 LOF signature remained an independent
prognostic factor for PFS in multivariable analysis after
controlling for tumor stage (Fig.
S6).
To further investigate the feasibility of this
signature in predicting the efficacy of first-line chemotherapy in
LUSC, a total of 24 patients with LUSC treated with first-line
radiochemotherapy were respectively analyzed. These patients were
allocated into three groups based on the Amp(9G) and TP53
LOF status. Therefore, TP53 LOF combined with Amp(9G) was
not associated with PFS (P=0.419; Fig.
S7), indicating that its prognostic value could be specific to
patients receiving first-line chemotherapy alone, and not to those
treated with concurrent first-line radiochemotherapy.
Discussion
Although targeted therapy and immunotherapy have
markedly improved cancer treatment (32,33),
their efficacy in patients with LUSC remains limited (34,35).
Consequently, chemotherapy still plays a notable role in the
management of LUSC (36).
Therefore, the identification of reliable biomarkers for predicting
chemotherapy response and clinical response is urgently needed.
Although comparative analysis revealed marginally
significant differences in terms of smoking history and tumor stage
between the overall cohort and the chemotherapy cohort, no
significant differences were observed in individual TNM components
(Table I). These results indicated
a comparable background in TNM stage between the two cohorts.
Moreover, clinical stage was included in the multivariate analyses,
in which the identified biomarker (TP53 LOF and Amp(9G)
remained an independent predictor of prognosis, indicating that the
observed prognostic value is unlikely to be driven by these
baseline differences. In the present study, NMF analysis was
performed to genomic profiling data to cluster molecular subtypes.
NMF is a commonly used clustering approach for identifying
characteristic gene modules in cancer and has been successfully
applied to stratify prognosis in several types of cancer, including
pancreatic cancer, head and neck squamous carcinoma, hepatocellular
carcinoma and glioblastoma (37–40).
Although several molecular subtypes associated with prognosis in
LUSC have been previously reported (41,42),
to the best of our knowledge, the present study was the first to
employ NMF-based analysis of genomic alterations to assess
chemotherapy efficacy and predict prognosis in patients with
LUSC.
Studies have reported that TP53, CDKN2A, PTEN,
PIK3CA, Kelch like ECH associated protein 1, mixed-lineage leukemia
2, major histocompatibility complex class I A, nuclear factor
erythroid 2-related factor 2, NOTCH1 and RB1 are notably
altered in LUSC, with TP53 alterations present in the
majority of cases (8,43–46).
Consistent with the previous reports, in the present study,
TP53 alterations were detected in 91% of patients with LUSC.
In addition, PIK3CA (46%), CDKN2A (24%) and
PTEN (15%) were among the most commonly altered genes. In
LUSC, 8p11 (FGFR1 and Wolf-Hirschhorn syndrome candidate
1-like 1), 7p11 (EGFR), 11q13 (CCDN1) and 4q12
(KDR, KIT and PDGFRA) amps have also been frequently
reported (8,45,47).
In the present study, FGFR1 amp was identified in 16% of
patients with LUSC, which was consistent with previous studies
(48,49). Overall, the aforementioned findings
indicated that there was no patient selection bias in the present
study.
A total of 309 patients with LUSC were classified
into four molecular clusters based on their genomic alterations
using NMF analysis, including C1 (TP53 alterations), C2
(PIK3CA amp), C3 (CCND1, FGF19, FGF3 and FGF4
amp) and C4 (FGFR1, KDR, KIT and PDGFRA amp).
Subsequently, the present study investigated whether these
NMF-based molecular clusters could predict the efficacy of
chemotherapy in patients with LUSC. LUSC is characterized by a high
rate of CNVs compared with other types of cancer (50). Recurrent amplifications involving
SOX2, PIK3CA, PDGFRA/KIT, FGFR1, CCND1 and FGF3/4/19 are
commonly observed in LUSC (50,51).
CNVs represent a hallmark of chromosomal instability (CIN) in
cancer (52). More particularly,
Teixeira et al (53)
indicated that CIN, characterized by widespread copy number
alteration, could be detected at the pre-malignant stage. CIN has
been shown to exert dual effects on tumor progression. Therefore,
although moderate levels of CIN can promote tumor evolution via
increasing intratumoral heterogeneity and contributing to
therapeutic resistance (54),
excessive CIN can exceed cellular tolerance to genomic stress and
induce tumor cell death, particularly in the context of DNA
damage-based therapies such as chemotherapy (55).
TP53, a well-established tumor suppressor
gene, is commonly mutated across a wide spectrum of cancer types.
As a sequence-specific transcription factor, TP53 protein plays a
key role in regulating the expression of adjacent genes via binding
to specific DNA sequences (56,57).
TP53 deficiency can lead to multifaceted oncogenic
consequences, including impaired cell cycle control, compromised
apoptotic signaling and enhanced genomic instability (57,58).
Different types of cancer can actively evade chemotherapy-induced
DNA damage-dependent cell senescence and apoptosis through
synergistic interactions. Emerging evidence has suggested that
TP53 LOF drives tumor metastasis, disease progression and
resistance to chemotherapy (29,59–61).
Consistent with these findings, in the present retrospective
cohort, TP53 LOF, arising from frameshift mutations, splice
site mutations, copy number deletions and nonsense mutations, was
significantly associated with shorter mPFS in patients with LUSC
treated with first-line chemotherapy. This association was also
independently validated in the TCGA-LUSC cohort, indicating that
TP53 LOF could be a robust predictor of worse prognosis in
patients with LUSC receiving first-line chemotherapy.
In the present study, both TP53 LOF and
NMF-based molecular clustering could predict chemotherapy efficacy
in LUSC. In addition, whether TP53 combined with NMF-based
molecular clustering could improve prognostic stratification was
subsequently explored. For clinical practicality, clusters C2/3/4,
each characterized by gene amp and similar PFS behavior, were
grouped together. Therefore, a simplified biomarker signature based
on Amp(9G) (PIK3CA, CCND1, FGF19, FGF3, FGF4, FGFR1, KDR,
KIT and PDGFRA) combined with TP53 status was
established. Using the aforementioned approach, the results
demonstrated that Amp(9G) without TP53 LOF exhibited the
most favorable PFS, while patients with TP53 LOF without
Amp(9G) experienced the worst PFS, both in the retrospective and
TCGA validation cohorts. This finding could be because increased
CIN mediated by gene amp could represent a specific vulnerability
of tumor cells. Supra-threshold CIN can potentially induce tumor
cell death (62,63). Notably, the combination of Amp(9G)
and TP53 LOF failed to predict prognosis in
radiochemotherapy-treated patients with LUSC. These findings
suggested that Amp(9G) combined with TP53 LOF could serve as
a feasible tool for predicting prognosis in patients with LUSC
receiving chemotherapy in clinical practice.
However, the present study has some limitations that
should be acknowledged. Although significant differences in PFS
were observed among groups stratified by Amp(9G) combined with
TP53 LOF in the retrospective LUSC cohort, statistical
significance was not reached in the TCGA-LUSC cohort, despite a
consistent trend. The aforementioned discrepancy could reflect
differences in the populations studied, with the retrospective
cohort comprising Chinese patients and the TCGA-LUSC cohort
representing a Western population. Additionally, the distribution
of tumor stage was different between the two cohorts with stage
III/IV predominating in the retrospective cohort and stage I/II
being more common in the TCGA-LUSC cohort. The chemotherapy cohort
was relatively small and included heterogeneous platinum-based
regimens, which precluded detailed stratified or multivariable
analyses according to specific treatments and may introduce
residual confounding. Therefore, larger, prospective cohort studies
are needed to further validate the predictive and prognostic value
of the Amp(9G) and TP53 LOF signature in patients with LUSC
treated with first-line chemotherapy.
In conclusion, in the present study, NMF-based
molecular clustering to genomic data was applied to predict the
efficacy of first-line chemotherapy in patients with LUSC. An
applicable biomarker signature encompassing Amp(9G) and TP53
LOF was developed and the performance of this signature was
validated in the TCGA-LUSC cohort and patients who received
radiochemotherapy. The results suggested that Amp(9G) without
TP53 LOF could serve as a favorable prognostic biomarker for
patients with LUSC receiving chemotherapy.
Supplementary Material
Supporting Data
Supporting Data
Acknowledgements
Part of the present study was previously published
as a meeting abstract at the American Association for Cancer
Research Annual Meeting 2023 in Orlando, USA and appeared in
Cancer Res (2023) 83 (7_Supplement): Abstract no. 5470.
Funding
Funding: No funding was received.
Availability of data and materials
The raw sequencing data generated in the present
study can be found in the officially designated repository in
China, Genome Sequence Archive for Human (GSA-Human: HRA016539)
that are publicly accessible at: https://ngdc.cncb.ac.cn/gsa-human/browse/HRA016539.
The datasets are under controlled access. Researchers interested in
obtaining the data can apply for permission through the GSA-Human
application system. Upon approval by the Data Access Committee
(DAC), authorized users can download the data. The verification
data generated and analyzed in the present study are available from
the PanCanAtlas dataset, which is publicly available at
https://gdc.cancer.gov/about-data/publications/pancanatlas.
Authors' contributions
YL participated in the study design and data
curation and was responsible for writing original draft. TH and HL
contributed to the data analysis and methodological validation. HD
wrote the original manuscript with YL and performed bioinformatics
data processing. LQ and YZ contributed to the data acquisition and
visualization. GZ designed the methodology and provided
supervision. YT contributed to the conceptualization, revised the
manuscript and performed the project administration. YL and TH
confirm the authenticity of the raw data. All authors read and
approved the final version of the manuscript.
Ethics approval and consent to
participate
This retrospective study utilized existing clinical
records, and all patient data and samples were rigorously
de-identified prior to analysis. The tissue analysis using a
56-gene panel in the retrospective study was part of standard
clinical care, not a research-specific assay. Therefore, the full
study protocol which included a waiver of the requirement for
informed consent based on the use of anonymized data was reviewed
and approved by the Ethics Committee of West China Hospital
(approval no. 2022-1849).
Patient consent for publication
Not applicable.
Competing interests
The authors declare that they have no competing
interests.
Glossary
Abbreviations
Abbreviations:
|
Amp(9G)
|
amplification of at least one of nine
genes
|
|
CNV
|
copy number variation
|
|
CIN
|
chromosomal instability
|
|
FFPE
|
formalin-fixed paraffin-embedded
|
|
Indel
|
insertions and deletions
|
|
KSCC
|
keratinizing squamous cell
carcinoma
|
|
LGR
|
large genomic rearrangement
|
|
LOF
|
loss-of-function variations
|
|
LUAD
|
lung adenocarcinoma
|
|
LUSC
|
lung squamous cell carcinoma
|
|
NGS
|
next-generation sequencing
|
|
NKSCC
|
non-keratinizing squamous cell
carcinoma
|
|
NMF
|
non-negative matrix factorization
|
|
PFS
|
progression-free survival
|
|
SNP
|
single-nucleotide polymorphisms
|
|
SNVs
|
single nucleotide variations
|
|
TCGA
|
The Cancer Genome Atlas
|
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![Validation of the prognostic
potential of TP53 LOF alone or combined with Amp(9G) in the
TCGA LUSC cohort treated with chemotherapy. (A) PFS stratified by
TP53 LOF status in the TCGA LUSC cohort. (B) PFS comparison
among patients harboring TP53 LOF without Amp(9G), Amp(9G)
without TP53 LOF and others [including those with Amp(9G)
and TP53 LOF, and those without Amp(9G) and TP53
LOF]. LOF, loss-of-function; TCGA, The Cancer Genome Atlas; LUSC,
lung squamous cell carcinoma; PFS, progression-free survival; amp,
amplification; Amp(9G), amplification of at least one of nine
genes.](/article_images/ol/32/1/ol-32-01-15644-g03.jpg)
